KR100454423B1 - Apparatus for controlling brightness of Cold Cathode Fluorescent Lamp - Google Patents

Abstract

The present invention relates to a cold cathode tube brightness control apparatus for equalizing a plurality of cold cathode tubes.

Cold cathode tube brightness control device of the present invention is provided with a high voltage generator for generating an AC high voltage signal by receiving a predetermined signal to the primary winding main line and induces the secondary winding in proportion to a predetermined winding ratio, the secondary winding main winding One end is connected to the upper end and the lower end, respectively, to the first and second capacitors for transmitting the AC high voltage signal generated from the high voltage generator to the first and second cold cathode tubes, and the other ends of the first and second capacitors, respectively. One end is connected to each other, and one end is connected to each of the first and second cold cathode tubes which are turned on by receiving a predetermined signal transmitted through the first and second capacitors, and the other end of the first and second cold cathode tubes, respectively. First and second resistors having one end connected to the other end of the ground terminal, respectively, the secondary main winding of the high voltage generating section, the first capacitor, the first cold cathode tube, the second cold cathode tube, and the second capacitance. And a current detector for forming a closed loop through interconnection with the rotor.

According to the present invention, the brightness of the two cold cathode tubes can be kept the same, and the brightness in each cold cathode tube can be kept constant.

Description

{Apparatus for controlling brightness of Cold Cathode Fluorescent Lamp}

The present invention relates to a cold cathode tube brightness control device, and more particularly to a cold cathode tube brightness control device that controls the same number of cold cathode tube brightness, and to control the brightness in each cold cathode tube is constant.

Recently, a thin PDP (Plasma Display Panel) or LCD (Liquid Crystal Display) panel has been used as a display device. In particular, as a display device, an LCD panel is easy to apply to a screen having a relatively small size compared to a PDP, and is widely used due to its low cost.

However, these LCD panels are not bright enough to support the brightness of the screen through the back light (Back Light). A cold cathode tube (CCFL: Cold Cathode Fluorescent Lamp) is generally used for the backlight, and an inverter is used to turn on the cold cathode tube.

Hereinafter, embodiments of a cold cathode tube brightness control apparatus for controlling the brightness of the cold cathode tube using an inverter will be described with reference to the accompanying drawings.

1 is a circuit diagram of a cold cathode tube brightness control apparatus according to a first embodiment of the present invention. As shown in FIG. 1, the cold cathode tube brightness control apparatus includes a DC voltage converter 1, a choke coil CL ₁ , and a switching circuit. Part 2, transformer 3, first cold cathode tube 4, second cold cathode tube 5, control unit 6, first resistor R ₁ , second resistor R ₂ and first to Third capacitors C ₁ to C ₃ are provided.

The controller 6 adjusts the voltage level of the signal output from the DC voltage converter 1 to vary the AC high voltage signal level induced by the secondary main winding L ₂ of the transformer 3 so as to change the first and second voltages. Cold cathode tubes 4, 5 are controlled to be constant in brightness.

FIG. 2 shows the first and second cold cathode tubes 4 and 5, the reflector plate A, and the parasitics when the first and second cold cathode tubes 4 and 5 shown in FIG. It is a diagram briefly showing a connection structure of capacities. As shown in FIG. 2, each of the first and second cold cathode tubes 4 and 5 is connected to the reflecting plate A through parasitic capacitance.

Parasitic capacitances are an electrical representation of the leakage of the tube current flowing through the first and second cold cathode tubes (4) (5).

Here, when the tube current flows through the cold cathode tube, the amount of current leaking into the reflecting plate through the parasitic capacitances will be described with reference to FIG. 3.

As shown in FIG. 3, a current (ie, 5.5 mA) corresponding to an alternating current high voltage signal induced in the secondary main winding of the transformer is connected to the upper end of the secondary main winding of the transformer (ie, a ballast capacitor). Is input to the cold cathode tube. The current input to the cold cathode tube is 5.35 mA, but after passing through the cold cathode tube due to current leakage by the parasitic capacitances while passing through the cold cathode tube, the amount of current output is 5 mA. That is, it can be seen that a predetermined current (about 0.5 mA) leaks through parasitic capacitances connected between the cold cathode tube and the reflector. In addition, leakage of current through parasitic capacitances results in partial brightness differences within a single cold cathode tube.

Therefore, it is desirable that the parasitic capacitances be designed in a structure so that the brightness in the cold cathode tube is kept constant.

4 is a circuit diagram of a cold cathode tube brightness control apparatus according to a second embodiment of the present invention. Here, the interaction relationship between the DC voltage converter 10, the choke coil CL ₁₁ , the first resistor R ₁₁ , the switching unit 11, and the controller 15 may be represented by the respective DC voltage converters illustrated in FIG. 1. 1), since the choke coil CL ₁ , the first resistor R ₁ , the switching unit 2, and the control unit 6 are the same as each other, the overlapping description is omitted.

As shown in FIG. 4, the first and second cold cathode tubes 13 and 14 are connected in a line through the first capacitor C ₁₁ to the upper side of the main winding L ₁₂ of the transformer 12. have. For this reason, the AC high voltage signal level induced by the secondary main winding L ₁₂ of the transformer ₁₂ is higher than the AC high voltage signal level induced by the secondary main winding L ₁₂ of the transformer 3 shown in FIG. 1. The voltage is about twice as high.

The controller 15 detects the tube current flowing through the first and second cold cathode tubes 13 and 14 through the second resistor R ₁₂ , and according to the detected current value, the first and second cold cathode tubes. (13) It is determined whether the brightness of 14 corresponds to the reference brightness and operates in the same way as the control function of the controller 6 shown in FIG.

FIG. 5 shows the first and second cold cathode tubes 13 and 14, the reflector plate B, and the parasitics when the first and second cold cathode tubes 13 and 14 shown in FIG. 4 are used as backlights of the LCD. It is a diagram briefly showing a connection structure of capacities.

However, the cold cathode tube brightness control device according to the prior art of the first embodiment are connected in parallel first and second capacitors (C ₁₎ (C ₂₎ each of the impedance deviation and, first and second capacitors (C ₁₎ (C ₂ ) the amount of tube current flowing through the first cold cathode tube 4 and the second cold cathode tube 5 is not equal due to the impedance deviation in the first and second cold cathode tubes 4 and 5 connected to each other. There is a problem in that the first cold cathode tube 4 and the second cold cathode tube 5 cannot be turned on at the same brightness.

In addition, when any cold cathode tube (for example, the first cold cathode tube 4) of the 1st and 2nd cold cathode tubes 4 and 5 is broken and does not light, it is necessary for the 2nd cold cathode tube 5 By generating the above tube current, there is a problem of shortening the life of the second cold cathode tube 5 or damaging the second cold cathode tube 5.

The cold cathode tube brightness control apparatus according to the second embodiment of the present invention connects the first and second cold cathode tubes 13 and 14 in a row so that the same tube current flows, thereby making the two cold cathode tubes 13 and 14 identical. Although it can be lit with brightness, the starting voltage for lighting the two cold cathode tubes 13, 14 connected in series is about twice more than the starting voltage for lighting the two cold cathode tubes 4, 5 of the first embodiment. By applying high, as shown in Fig. 5, each parasitic capacitance due to mechanical imbalance leaks a larger amount of current than a typical leakage current amount (about 0.5 mA), so that in each cold cathode tube 13, 14, There is a problem of generating a partial brightness difference in.

The present invention has been made to solve the above problems, by controlling the same amount of tube current flow through a plurality of cold cathode tubes to maintain the same brightness of each cold cathode tube, the parasitic capacitance between each cold cathode tube and reflector It is an object of the present invention to provide a cold cathode tube brightness control device for maintaining a constant brightness in each cold cathode tube by minimizing current leakage.

1 is a circuit diagram of a cold cathode tube brightness control apparatus according to a first embodiment of the present invention;

2 is a view showing the cold cathode tube connection structure of Figure 1 used as a backlight of the LCD panel,

3 is a view showing the amount of leakage current between the cold cathode tube and the reflector used as a backlight of the LCD panel,

4 is a circuit diagram of a cold cathode tube brightness control apparatus according to a second embodiment of the present invention;

5 is a view showing the cold cathode tube connection structure of Figure 4 used as a backlight of the LCD panel,

6 is a circuit diagram of a cold cathode tube brightness control apparatus according to an embodiment of the present invention,

7 is a view showing the cold cathode tube connection structure of Figure 6 used as a backlight of the LCD panel,

8 is a circuit diagram of a cold cathode tube brightness control apparatus according to another embodiment of the present invention;

9 is a view showing the cold cathode tube connection structure of Figure 8 used as a backlight of the LCD panel.

* Description of the symbols for the main parts of the drawings *

100: DC voltage conversion unit 110: switching unit

120: high voltage generating unit 130: first cold cathode tube

140: second cold cathode tube 150: current detection unit

160: voltage rectifying unit 170: control unit

CL ₁₀₀ : Choke coil C ₁₁₀ to C ₁₃₀ : First to third capacitor

R ₁₁₀ to R ₁₃₀ : first to third resistors

D ₁₁₀ to D ₁₃₀ : first to third diodes

S ₁₁₀ to S ₁₃₀ : first to third switches

The brightness control device of the cold cathode tube according to the present invention for achieving the above object is provided with a high voltage generator for generating an AC high voltage signal by receiving a predetermined signal to the primary winding main line and induces the secondary winding to the secondary winding in proportion to the predetermined winding ratio. In the cold cathode tube brightness control device, one end is connected to the upper and lower ends of the secondary main winding of the high voltage generator, and the first and second to transmit the AC high voltage signal generated from the high voltage generator to the first and second cold cathode tube; A first capacitor and a second cold cathode tube connected to one end of each of the first and second capacitors, the first and second cold cathode tubes being turned on by receiving a predetermined signal transmitted through the first and second capacitors; One end of each of the first and second cold cathode tubes is connected to one end, and the first and second resistors of the other end are respectively connected to the ground terminal. It includes a main winding, a first capacitor, a first cold cathode tube, a second cold cathode tube, and a current detection unit that forms a closed loop through interconnection with a second capacitor.

In addition, the cold cathode tube brightness control apparatus of the present invention for achieving the above object is provided with a high voltage generator for generating an AC high voltage signal by receiving a predetermined signal to the primary winding main line and induces the secondary winding in proportion to a predetermined winding ratio A cold cathode tube brightness control apparatus comprising: first and second cold cathode tubes having one end connected to an upper end and a lower end of a secondary main winding of a high voltage generating unit, the first and second cold cathode tubes being turned on by receiving an AC high voltage signal generated from the high voltage generating unit; A second main winding of the high voltage generating unit, a first cold cathode tube, having first and second resistors having one end connected to the other end of each of the first and second cold cathode tubes, and the other end connected to the ground end thereof, respectively; And a current detector for forming a closed loop through interconnection with the second cold cathode tube.

Hereinafter, preferred embodiments of the cold cathode tube brightness control apparatus of the present invention will be described with reference to the drawings.

6 is a circuit diagram of a cold cathode tube brightness control apparatus according to an embodiment of the present invention, as shown in Figure 6, the cold cathode tube brightness control apparatus of the present invention is a DC voltage converter 100, choke coil (CL) ₁₀₀ ), the switching unit 110, the high voltage generating unit 120, the first cold cathode tube 130, the second cold cathode tube 140, the current detector 150, the voltage rectifier 160, the controller 170, the first It is configured to include one to third capacitors (C ₁₁₀ ~ C ₁₃₀ ).

The DC voltage converter 100 includes a first switch S _{110 that} receives a DC voltage Vin in a predetermined range, and a third diode D ₁₃₀ . The cathode terminal of the third diode D ₁₃₀ is connected to the first switch S ₁₁₀ , and the anode terminal is connected to the ground terminal.

One end of the choke coil CL ₁₀₀ is connected to the output terminal of the DC voltage converter 100, and the other end thereof is connected to the center end of the primary main winding L ₁₁₀ of the high voltage generator 120.

One end of the third resistor R ₁₃₀ is connected in parallel between the choke coil CL ₁₀₀ and the primary main winding L ₁₁₀ of the high voltage generator 120, and the other end is connected to the switching unit 110. do.

The switching unit 110 includes second and third switches S ₁₂₀ and S ₁₃₀ . One end of the second switch S ₁₂₀ is connected to the upper end of the primary main winding L ₁₁₀ of the high voltage generator 120, and the other end is connected to the ground terminal. One end of the third switch S ₁₃₀ is connected to the lower end of the primary main winding L ₁₀₀ of the high voltage generator 120, and the other end is connected to the ground terminal. Here, the second switch S ₁₂₀ is turned on / off as a signal is input through the third resistor R ₁₃₀ , and the third switch S ₁₃₀ is a primary auxiliary winding L of the high voltage generator 120. ₁₃₀ is on / off as a predetermined signal is induced. The second and third switches S ₁₂₀ and S ₁₃₀ alternately perform an 'on / off' operation in cooperation with each other.

One end of the third capacitor C ₁₃₀ is simultaneously connected to an upper end of the primary main winding L ₁₁₀ of the high voltage generator 120 and one end of the second switch S ₁₂₀ , and the other end of the third primary winding is connected to the primary main winding. ₍₁₁₀ L) and the lower end is simultaneously connected to the third switch (S _130), it forms a parallel configuration with the primary windings (L ₁₁₀₎ of the high voltage generating part (120).

One end of the first capacitor C ₁₁₀ is connected to the upper end of the secondary main winding L ₁₂₀ of the high voltage generator ₁₂₀ , and the other end thereof is connected to one end of the first cold cathode tube 130.

One end of the second capacitor C ₁₂₀ is connected to the lower end of the secondary main winding L ₁₂₀ of the high voltage generator ₁₂₀ , and the other end thereof is connected to one end of the second cold cathode tube 140.

The current detector 150 includes first and second resistors R ₁₁₀ and R ₁₂₀ . One end of the first resistor R ₁₁₀ is connected to the other end of the first cold cathode tube 130, and one end of the second resistor R ₁₂₀ is connected to the other end of the second cold cathode tube 140. The other end is simultaneously connected to the other end of the first resistor R ₁₁₀ and the ground terminal.

Here, the secondary main winding L ₁₂₀ of the high voltage generator 120, the first capacitor C ₁₁₀ , the first cold cathode tube 130, and the first and second resistors R of the current detector 150. ₁₁₀ ) R ₁₂₀ , the second cold cathode tube 140, and the second capacitor C ₁₂₀ are connected to each other to form a closed loop.

The voltage rectifier 160 includes first and second diodes D ₁₁₀ and D ₁₂₀ . The anode terminal of the first diode D _{110 is} connected between the first cold cathode tube 130 and the first resistor R ₁₁₀ of the current detector 150, and the anode terminal of the second diode D ₁₂₀ is connected to the second terminal. The cold cathode tube 140 and the second resistor R ₁₂₀ of the current detector 150 are connected, and the cathode terminal of the second diode D ₁₂₀ is connected to the cathode terminal of the first diode D ₁₁₀ .

Hereinafter, the operation of the cold cathode tube brightness control apparatus according to an embodiment of the present invention will be described in detail.

First, the DC voltage converter 100 receives a DC voltage Vin in a predetermined range and converts the DC voltage Vin into a square wave signal having a constant voltage level according to the control signal of the controller 170 to output the choke coil CL ₁₀₀ . .

That is, when the 'on' control signal is transmitted from the control unit 170, the first switch (S ₁₁₀ ) and the third diode (D ₁₃₀ ) of the DC voltage conversion unit 100 is' When the DC voltage Vin is switched on and off and the 'off' control signal is transmitted from the controller 170, the first switch S ₁₁₀ and the third diode D ₁₃₀ are turned off. During the control signal period, each is' off / on 'to switch'0'V to output a square wave signal having a predetermined voltage level.

Here, the voltage level of the square wave signal output from the DC voltage converter 100 is determined according to the duty ratio of the 'on / off' control signal transmitted from the controller 170. That is, when the duty ratio of the 'on / off' control signal increases in the 'on / off' control signal having a predetermined period, the 'on' control signal section is increased and the 'off' control signal section is relatively decreased, so that the DC voltage converter The voltage of the square wave signal output from 100 increases by a predetermined level. Meanwhile, when the duty ratio of the 'on / off' control signal decreases, the 'on' control signal section decreases and the 'off' control signal section increases relatively, so that the voltage of the square wave signal output from the DC voltage converter 100 Decreases by a predetermined level.

Subsequently, the choke coil CL ₁₀₀ generates a current signal by adding an inductance component to the square wave signal output from the DC voltage converter 100.

The high voltage generator 120 receives the current signal transmitted through the choke coil CL ₁₀₀ through the primary winding L ₁₁₀ and induces an AC high voltage signal having a sinusoidal wave shape by inducing it to the secondary side in proportion to a predetermined winding ratio. . Here, the sinusoidal AC high voltage signal is a signal that resonates up and down with the central portion of the secondary voltage main winding L ₁₂₀ as the reference point, that is, the zero point.

In this case, the switching unit 110 receives a current signal transmitted from the choke coil CL ₁₀₀ as a predetermined voltage signal through a third resistor R _{130 and} turns on / off the first signal of the high voltage generator 120. thereby switching the primary side windings (L _110), the current signal alternating voltage signal of the sine wave generated in the primary side windings (L ₁₁₀₎ by the application to the secondary side windings (L ₁₂₀₎ of the high voltage generating unit 120 . Here, the second and third switches S ₁₂₀ and S ₁₃₀ of the switching unit 110 operate on / off so that the AC high voltage signal is continuously induced to the secondary main winding L ₁₂₀ of the high voltage generator ₁₂₀ . Repeat.

Subsequently, the first and second cold cathode tubes 130 and 140 are connected to both ends of the secondary main winding L ₁₂₀ of the high voltage generator ₁₂₀ , respectively, C ₁₁₀ and C _120. The lamp is turned on by receiving an AC voltage signal of a predetermined level.

That is, the first cold cathode tube 130 receives the AC high voltage signal resonating in the positive direction with the center of the secondary main winding L ₁₂₀ as the reference point as the first capacitor. It receives the input through (C ₁₁₀ ), and the second cold cathode tube 140 resonates in the negative direction with the central portion of the secondary main winding L ₁₂₀ as the reference point as the reference point. The AC high voltage signal is input through the second capacitor C _{120 and} is turned on.

Here, the secondary main winding L ₁₂₀ of the high voltage generator 120, the first capacitor C ₁₁₀ , the first and second resistors R ₁₁₀ (R ₁₂₀ ) of the current detector 150, and Since the second cold cathode tube 140 and the second capacitor C ₁₂₀ are connected to each other in series to form a closed loop, an AC voltage applied to the first and second cold cathode tubes 130 and 140 in the closed loop. A single tube current flows in response to the signal. The tube current is also an alternating current that resonates up and down.

As a result, the first and second cold cathode tubes 130 and 140 are turned on at the same brightness.

Subsequently, the current detector 150 detects a tube current flowing in the closed loop through the first and second resistors R ₁₁₀ and R ₁₂₀ , and outputs a voltage signal corresponding to the detected tube current to the voltage rectifier 160.

The voltage rectifier 160 rectifies the voltage signal output from the current detector 150 through the first and second diodes D ₁₁₀ and D ₁₂₀ to output a half-wave voltage signal.

The controller 170 estimates the amount of tube current flowing in the closed loop from the half-wave voltage signal rectified by the voltage rectifying unit 160, and the estimated tube current amount is more than or less than a preset current amount (hereinafter referred to as 'reference current amount'). The voltage level of the square wave signal output from the DC voltage generator 100 is controlled according to the recognition.

That is, when the estimated tube current amount is equal to or greater than the reference current amount, the controller 170 determines the brightness of the first and second cold cathode tubes 130 and 140 to be equal to or greater than the reference brightness, and thus the duty of the 'on / off' control signal. When the ratio is reduced and output to the DC voltage converter 100 and the estimated tube current is less than the reference current, the brightness of the first and second cold cathode tubes 130 and 140 is determined to be less than the reference brightness. The duty ratio of the on / off 'control signal is increased and output to the DC voltage converter 100.

The DC voltage generator 100 transmits a square wave signal having a voltage level lower than that of the input DC voltage Vin when the 'on / off' control signal having a reduced duty ratio is transmitted from the controller 170. When the 'on / off' control signal with increased duty ratio is transmitted from the control unit 170, the DC voltage Vin is converted into a square wave signal having a higher voltage level than before.

Accordingly, the controller 170 may vary the voltage level of the square wave signal output from the DC voltage converter 100 to be applied to the first and second cold cathode tubes 130 and 140 through the high voltage generator 120. By adjusting the voltage signal level, the brightness of the first and second cold cathode tubes 130 and 140 is always kept constant.

FIG. 7 illustrates the first and second cold cathode tubes 130 and 140, the reflector plate A10, and the parasitics when the first and second cold cathode tubes 130 and 140 shown in FIG. 6 are used as backlights of the LCD. A diagram showing a connection structure of capacities.

8 is a circuit diagram of the cold cathode tube brightness control apparatus according to another embodiment of the present invention, the DC voltage generator 200, the choke coil (CL ₂₀₀ ), the switching unit 210, high voltage generator 220, The first to third capacitors C ₂₁₀ to C ₂₃₀ , the first cold cathode tube 230, the second cold cathode tube 240, and the controller 270 may include the DC voltage generator 100 and the choke coil illustrated in FIG. 6. CL ₁₀₀ ), the switching unit 110, the high voltage generator 120, the first to third capacitors C ₁₁₀ to C ₁₃₀ , the first cold cathode tube 130, the second cold cathode tube 140, and the controller 170. ) Are the same as each, so duplicate description thereof will be omitted.

The current detector 250 illustrated in FIG. 8 includes a first resistor R ₂₁₀ . One end of the first resistor R ₂₁₀ is connected to the first cold cathode tube 230, and the other end thereof is simultaneously connected to the second cold cathode tube 240 and the ground terminal.

The voltage rectifier 260 includes a first diode D ₂₁₀ . The anode terminal of the first diode D ₂₁₀ is connected between the first cold cathode tube 230 and the first resistor R ₂₁₀ of the current detector 250, and the cathode terminal is connected to the input terminal of the controller 270. .

The current detector 250 includes the secondary main winding L ₂₂₀ , the first capacitor C ₂₁₀ , the first cold cathode tube 230, the second cold cathode tube 240, and the second capacitor of the high voltage generator ₂₂₀ . C ₂₂₀ detects a current flowing in the closed loop formed by being connected in series with each other.

Subsequently, the voltage rectifier 260 rectifies a voltage corresponding to the current detected by the current detector 250 and transmits the voltage to the controller 270.

The controller 270 predicts the amount of current flowing in the closed loop from the voltage rectified by the voltage rectifying unit 260 to control the first and second cold cathode tubes 230 and 240 to be turned on at a constant brightness. Hereinafter, since the control unit 270 is made the same as the operation process of the control unit 170 shown in FIG. 6, redundant description thereof will be omitted.

FIG. 9 illustrates the first and second cold cathode tubes 230 and 240, the reflector plate B10, and the parasitics when the first and second cold cathode tubes 230 and 240 shown in FIG. 8 are used as backlights of the LCD. A diagram showing a connection structure of capacities.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be embodied in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

Cold cathode tube brightness control apparatus according to the present invention as described above has the following advantages.

First, the two cold cathode tubes are connected to the high voltage generator, that is, the upper and lower ends of the secondary main winding of the transformer, respectively, to form a closed loop, and a single current flows through the two cold cathode tubes forming the closed loop to improve the brightness of the two cold cathode tubes. Can remain the same.

Second, by configuring the two cold cathode tubes in a closed loop form, it is possible to prevent overcurrent application to other cold cathode tubes in case of any breakdown of the cold cathode tubes, thereby preventing damage or shortening of the other cold cathode tubes in advance.

Third, unlike the conventional method of connecting two cold cathode tubes in series with the upper side of the secondary main winding of the transformer (that is, FIG. 4), the two cold cathode tubes may be configured in a closed loop to minimize current leakage through parasitic capacitance. Therefore, the brightness in each cold cathode tube can be kept constant.

Claims (4)

In the cold cathode tube brightness control device having a high voltage generating portion for receiving a predetermined signal to the primary winding main winding and induces the secondary winding winding in proportion to the predetermined winding ratio to generate an AC high voltage signal, First and second capacitors having one ends connected to upper and lower ends of the secondary main winding of the high voltage generator, and configured to transmit AC high voltage signals generated from the high voltage generator to first and second cold cathode tubes; First and second cold cathode tubes having one end connected to the other end of each of the first and second capacitors, respectively, being turned on by receiving a predetermined signal transmitted through the first and second capacitors; A second main winding of the high voltage generator, a first capacitor, and a first and second resistors having one end connected to each other at one end of the first and second cold cathode tubes, and one end connected to the other end at a ground terminal thereof. And a current detector configured to form a closed loop through interconnection between the first cold cathode tube, the second cold cathode tube, and the second capacitor. The method of claim 1, wherein the current detection unit And a tube current amount flowing through the first and second cold cathode tubes forming the closed loop. The method according to claim 1 or 2, A DC voltage converter converting a DC voltage of a predetermined range into a DC voltage signal of a predetermined level and outputting the DC voltage to the high voltage generator; A switching unit for receiving and driving a DC voltage signal output from the DC voltage changing unit to switch a predetermined signal input to the primary main winding of the high voltage generation unit to a secondary main winding of the high voltage generation unit; A voltage rectifying unit which receives a voltage signal corresponding to the amount of tube current detected by the current detecting unit, rectifies and outputs a predetermined signal; The tube current amount is predicted from a predetermined signal output from the voltage rectifying unit, and the DC current signal output from the DC voltage converter is varied according to the predicted tube current amount to control the tube current amount flowing through the first and second cold cathode tubes to be constant. Cold cathode tube brightness control device characterized in that it further comprises a control unit. In the cold cathode tube brightness control device having a high voltage generating portion for receiving a predetermined signal to the primary winding main winding and induces the secondary winding winding in proportion to the predetermined winding ratio to generate an AC high voltage signal, First and second cold cathode tubes each having one end connected to upper and lower ends of the secondary main winding of the high voltage generator and being lit by receiving an AC high voltage signal generated from the high voltage generator; One end is connected to the other end of each of the first and second cold cathode tubes, and the first and second resistors are connected to the other end of the first and second cold cathode tubes, respectively. And a current detector configured to form a closed loop through interconnection with the second cold cathode tube.