KR101015090B1 - Apparatus for driving of display panel - Google Patents

Abstract

PURPOSE: An apparatus for driving of a display panel is provided to block power supplied to a display panel from a DC-DC converter by sensing the excess of maximum driving current. CONSTITUTION: A DC-DC converter boosts a constant voltage to a driving voltage. The constant voltage is supplied from a power supply unit. An LDO regulator(30) drops the output voltage of a DC-DC converter and supplies The LDO regulator supplies a dropped output voltage to a display panel. Short sensors(40,50) senses whether a driving current exceeds maximum driving current. The short sensors control the output voltage of the DC-DC converter.

Description

A driving device of a display panel {APPARATUS FOR DRIVING OF DISPLAY PANEL}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving device of a display panel. In particular, when a power applied to the display panel is shorted due to a crack generated in the display panel, the present invention detects this and is applied to the display panel from the DC-DC converter. The present invention relates to a driving device of a display panel which can cut off power.

With the development of semiconductor manufacturing technology and image processing technology, commercialization and widespread use of flat panel display devices that can easily achieve light weight, thinness, and high image quality are rapidly progressing, and as such flat display devices, liquid crystal displays (Liquid Crystal Display) : LCD, Plasma Display Panel (PDP), Vacuum Florescent Display (VFD), Organic Light Emitting Diode (OLED), and the like.

Among the flat panel display devices, LCD, OLED, and the like are widely used in personal portable devices such as mobile phones, PDAs, portable computers, etc. due to light weight, thinness, and ease of definition, and particularly, external and internal windows of mobile phones having dual windows. It is used a lot for a dragon.

In particular, OLEDs are attracting attention as next-generation displays because they are thinner because they do not have a backlight such as an LCD as a self-luminous device and have a response speed of several tens of [ns], a wide viewing angle, and good contrast ratio.

As described above, as the display panel becomes thinner, cracks may also occur due to external impacts. When cracks occur in the display panel, a short occurs in power applied to the display panel. As a result, as the overcurrent flows through the display panel, the temperature rises, causing the display panel to burn. In addition, the short-circuit generated by the DC-DC converter is an overload condition, the DC-DC converter is destroyed, or the inductor (inductor) that is a peripheral component of the DC-DC converter is destroyed, which leads to the peripheral circuit There is a problem affecting.

Accordingly, in the related art, only a protection function for protecting a DC-DC converter or an inductor exists rather than a function for protecting the panel itself as a method for solving the above-mentioned problems.

Among the protection functions are the DC-DC converter's soft-start and thermal shutdown (TSD) functions.

However, according to the conventional TSD, when the temperature of the display panel drops below a certain temperature due to hysteresis characteristics, the TSD is restored and power is supplied from the DC-DC converter to the display panel again. There is a problem in that the power applied to the display panel from the DC-DC converter is cut off repeatedly by the TSD. In the case of a fine short in the driving region of the DC-DC converter (a few mA), it is not a complete short. There is a problem that the function does not work.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problem, and detects that the driving current applied to the display panel exceeds the preset maximum driving current due to the current generated by the micro shot while the display panel is driving. It is an object of the present invention to provide a driving device of a display panel that can cut off power applied to the display panel from a DC converter.

Another object of the present invention is to detect that the drive current applied to the display panel by the surrounding environment exceeds the maximum drive current of the display panel set by the inductor size value or the characteristics of the external components to apply to the display panel from the DC-DC converter It is possible to protect the inductor or external components by cutting off the power supply.

In order to achieve the above object, a display panel driving apparatus according to an embodiment of the present invention, the display panel; A DC-DC converter for boosting and outputting a constant voltage supplied from a power supply unit to a driving voltage of the display panel; A low drop output (LDO) regulator for stepping down the output voltage of the DC-DC converter to supply the display panel; A signal output from the error amplifier of the LDO regulator is applied to a gate terminal, and a sensing transistor to which an output voltage of the DC-DC converter is applied to a gate terminal and a drain terminal of the sensing transistor are sensed by the sensing transistor. And a comparator for converting a driving current into a voltage and a comparator for outputting a short detection signal by comparing the voltage converted by the resistor with a reference voltage. Able to detect whether a short occurs by detecting whether a drive current applied to the display panel exceeds the maximum drive current through the LDO regulator, and outputs a short detection signal to the DC-DC converter depending on whether a short occurs. The output voltage of the DC-DC converter It is preferably made by including a short circuit detection.

In addition, the sensing transistor of the short sensing unit may be implemented with a ratio of N: 1 to a pass transistor of the LDO regulator, and senses a driving current flowing through the pass transistor.

On the other hand, the display device driving apparatus according to another embodiment of the present invention, the display panel; A DC-DC converter for boosting and outputting a constant voltage supplied from a power supply unit to a driving voltage of the display panel; A low drop output (LDO) regulator for stepping down the output voltage of the DC-DC converter to supply the display panel; A signal output from an error amplifier of the LDO regulator is applied to a gate terminal, and a first sensing transistor to which an output voltage of the DC-DC converter is applied to a source terminal and a drain terminal of the first sensing transistor are connected to the first sensing transistor. And a first comparator for converting the driving current sensed by the one sensing transistor into a voltage and a first comparator for comparing the voltage converted by the first resistor with a reference voltage and outputting a short sensing signal. Enabled during the black data period in which no current should flow through the panel, and detects a short current applied to the display panel through the LDO regulator to detect whether a short occurs, and to the DC-DC converter according to whether a short occurs. First short sense to output short sense signal to control output voltage of DC-DC converter Unit; A signal output from the error amplifier of the LDO regulator is applied to a gate terminal, and a second sensing transistor to which an output voltage of the DC-DC converter is applied to a source terminal and a drain terminal of the second sensing transistor are connected to the second sensing transistor. And a second comparator for converting the driving current sensed by the second sensing transistor into a voltage and a second comparator for outputting a short sensing signal by comparing the voltage converted by the second resistor with a reference voltage. It is enabled during an image data period in which image data is applied to the panel, and detects whether a short occurs by detecting whether a driving current applied to the display panel through the LDO regulator exceeds a maximum driving current, and whether or not a short occurs. According to the output of the short detection signal to the DC-DC converter of the DC-DC converter It is preferable to include a second short detection unit for controlling the output voltage.

The first sensing transistor of the first short detector may be implemented with a ratio of N: 1 to a pass transistor of the LDO regulator, and senses a short current flowing through the pass transistor.

In addition, the second sensing transistor of the second short detector may be implemented with a ratio of N: 1 to a pass transistor of the LDO regulator, and senses a driving current flowing through the pass transistor.

According to the driving device of the display panel of the present invention, the driving of the display panel by detecting that the driving current applied to the display panel exceeds the preset maximum driving current due to the current generated by the fine short while the display panel is driving. In the meantime, it is possible to know whether or not a minute short in the driving region of the DC-DC converter has occurred. In addition, by cutting off the power applied to the display panel from the DC-DC converter depending on whether a short occurs, it is possible to prevent further damage to the display panel and to protect the DC-DC converter or inductor.

In addition, it detects that the driving current applied to the display panel by the surrounding environment exceeds the maximum driving current of the display panel set by the inductor size value or the characteristics of the external components, and cuts off the power applied to the display panel from the DC-DC converter. As a result, a current exceeding a current that can be accommodated by the inductor or the external component does not flow, thereby preventing heat generation in the inductor or the external component.

1 is a view schematically showing a driving device of a display panel according to an embodiment of the present invention.
2 is a circuit diagram illustrating a first short detector and a second short detector applied to the present invention.
3 and 4 are timing diagrams of an operation of a driving apparatus of a display panel according to an exemplary embodiment of the present invention.

Hereinafter, a driving apparatus of a display panel according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view schematically showing a driving apparatus of a display panel according to an embodiment of the present invention.

In FIG. 1, the power supply unit 10 supplies a constant voltage to the DC-DC converter 20.

The DC-DC converter 20 boosts and outputs the constant voltage supplied from the power supply unit 10 to the driving voltage of the display panel 60.

As described above, the DC-DC converter 20 includes a PWM controller 25 for controlling the driving of the DC-DC converter 20.

As described above, the PWM controller 25 controls the output voltage of the DC-DC converter 20 based on a signal applied from the first short detector 40 or the second short detector 50.

That is, when the low level signal is applied from the first short detector 40 or the second short detector 50, the PWM controller 25 may supply a voltage from the DC-DC converter 20 to the display panel 60. When a high level signal is applied from the first short detector 40 or the second short detector 50, the DC-DC converter 20 cuts off the voltage applied to the display panel 60. Let's do it.

Meanwhile, the LDO regulator 30 steps down the output voltage of the DC-DC converter 20 and supplies it to the display panel 60.

The first short detector 40 is implemented between the display panel 60 and the DC-DC converter 20, and is enabled during the black data period in which no current flows in the display panel 60, thereby enabling the LDO regulator 30. Through sensing the current applied to the display panel 60 from the DC-DC converter 20 detects the occurrence of a short, and outputs a short detection signal to the DC-DC converter 20 according to whether the short.

That is, when the driving power ELVDD and ELVSS applied to the display panel 60 are shorted due to the cracks generated in the display panel 60, a short current flows from the DC-DC converter 20 to the display panel 60.

However, when the crack generated in the display panel 60 is minute, the short current flowing from the DC-DC converter 20 to the display panel is small, so that the display panel 60 is driven by the conventional TSD or the current limit. You will not be able to detect it.

Accordingly, the first short detection unit 40 is enabled during the black data period in which no current flows in the display panel 60 when no crack is generated in the display panel 60, so that the DC-DC is applied during the black data period. The converter 20 detects whether a short current flows from the display panel 60. In this case, when no crack occurs in the display panel 60, a short current does not flow from the DC-DC converter 20 to the display panel 60, and when a crack occurs in the display panel 60, the DC-DC Short current flows from the converter 20 to the display panel 60.

As described above, the first short detector 40 which detects the short current during the black data period detects the short current and transmits the short detection signal to the PWM controller 25 of the DC-DC converter 20 according to the detection result. Is authorized.

Here, the black data section is a section in which black data is applied before the image data is applied to the display panel 60 according to the display panel driving signal. No current flows through the normal display panel 60 while the black data is applied. .

Meanwhile, the second short detector 50 is implemented between the display panel 60 and the DC-DC converter 20, and during the image data period in which the image data is applied to the display panel 60, that is, the display panel 60. Is driven while the driving current is applied to the display panel 60, and the driving current applied from the DC-DC converter 20 to the display panel 60 through the LDO regulator 30 is preset. Detects whether a short is generated by detecting whether the current is exceeded, and outputs a short detection signal to the DC-DC converter 20 according to whether a short occurs.

That is, when the driving power ELVDD and the ELVSS applied to the display panel 60 are shorted due to the minute cracks generated while the display panel 60 is being driven, the first short detection unit 50 may not detect them. do. In addition, when the crack generated during driving is minute, the short current flowing from the DC-DC converter 20 to the display panel is small, and thus the display panel 60 may be detected while the display panel 60 is driven by a conventional TSD or current limit. It becomes impossible.

Accordingly, the second short detector 50 is enabled during the image data period, so that the driving current applied from the DC-DC converter 20 to the display panel 60 while the driving current is applied to the display panel 60. Will detect if the maximum drive current is exceeded. In this case, when no crack is generated in the display panel 60, the driving current applied from the DC-DC converter 20 to the display panel 60 does not exceed the maximum driving current, and the crack is displayed in the display panel 60. In this case, the driving current applied from the DC-DC converter 20 to the display panel 60 exceeds the maximum driving current.

As described above, after detecting whether the driving current applied from the DC-DC converter 20 to the display panel 60 exceeds the preset maximum driving current while the display panel 60 is being driven, the DC- The short detection signal is applied to the PWM controller 25 of the DC converter 20.

2 is a circuit diagram illustrating a first short detector and a second short detector applied to the present invention.

As shown in FIG. 2, the first short detector 40 includes a first sensing transistor M1, a first resistor R _S 1, a first comparator 43, a first operational amplifier 45, and a first amplifier. One transistor M2 is included, and the second short detector 50 includes a second sensing transistor M3, a second resistor R _S 2, a second comparator 53, and a second operational amplifier 55. ) And a second transistor M4.

In such a configuration, the first sensing transistor M1 of the first short detection unit 40 may have a pass transistor M0 of the LDO regulator 30 and N: 1 (eg, 100: 1). The short current flowing through the pass transistor M0 is sensed during the black data period. In this case, since the magnitude of the current sensed by the first sensing transistor M1 varies according to the ratio of the pass transistor M0 and the first sensing transistor M1, the pass transistor M0 and the first sensing transistor ( By changing the ratio of M1), the level of the short current that can be detected by the first short detector 40 can be adjusted.

As described above, the first sensing transistor M1 may be implemented as a PMOS transistor. At this time, the signal output from the error amplifier 35 of the LDO regulator 30 is applied to the gate terminal of the PMOS transistor M1, and the output voltage V _M of the DC-DC converter 20 is applied to the source terminal. .

The first resistor R _S 1 is connected to the drain terminal of the first sensing transistor M1 to convert the short current I _SH 2 sensed by the first sensing transistor M1 into a first voltage V _Rs 1. Let's do it. At this time, the first resistance (R _S 1), the value a first voltage (V _Rs 1) dependent on the magnitude of the first resistance by changing the size of the (R _S 1) detected by the first short detection portion 40 The level of possible short current can be adjusted.

As described above, by changing the ratio of the pass transistor M0 and the first sensing transistor M1 and the size of the first resistor R _S 1, the first short detection unit 40 may detect the ratio. The level of the short current can be adjusted. Accordingly, the short current due to the minute short caused by the minute crack can also be detected.

Meanwhile, the first comparator 43 compares the first voltage V _Rs 1 converted by the first resistor R _S 1 and the first reference voltage V _ref 1 to output a short detection signal.

The first comparator 43 includes the DC-DC converter 20 until the first voltage V _Rs 1 converted by the first resistor R _S 1 becomes larger than the first reference voltage V _ref 1. Outputs a short detection signal of a low level to the PWM controller 25, and the first voltage V _Rs 1 converted by the first resistor R _S 1 is greater than the first reference voltage V _ref 1, or When the same, the high level short detection signal is output to the PWM controller 25 of the DC-DC converter 20.

Accordingly, the PWM controller 25 receiving the low level short detection signal from the first comparator 43 generates a PWM control signal and applies it to a switch transistor (not shown), thereby displaying it in the DC-DC converter 20. When the power is supplied to the panel 60 and the high level short detection signal is applied from the first comparator 43, the DC-DC converter is not generated by generating the PWM control signal output to the switch transistor (not shown). The power is not applied to the display panel 60 at 20.

On the other hand, the first short detector 40 may be configured such that the voltage across the drain terminal of the pass transistor M0 and the drain terminal of the first sensing transistor M1 is the same voltage. It may further comprise a transistor (M2).

The voltage applied to the drain terminal of the pass transistor M0 is input to the non-inverting input terminal (+) of the first operational amplifier 45 described above, and the drain of the first sensing transistor M1 is input to the inverting input terminal (-). The voltage across the terminal is input.

In addition, the first transistor M2 is implemented between the first sensing transistor M1 and the first resistor R _S 1 and according to the output voltage of the first operational amplifier 45 input through the gate terminal. The short current I _SH 2 output from the sensing transistor M1 is input through the source terminal and output to the first resistor R _S 1.

On the other hand, the second sensing transistor M3 of the second short detector 50 is implemented with a ratio between the pass transistor M0 of the LDO regulator 30 and N: 1 (eg, 100: 1). The display panel 60 is driven to sense the driving current flowing through the pass transistor M0 while the driving current is applied to the display panel 60. In this case, since the magnitude of the current sensed by the second sensing transistor M3 varies according to the ratio of the pass transistor M0 and the second sensing transistor M3, the pass transistor M0 and the second sensing transistor ( By changing the ratio of M3), it is possible to adjust the level of the driving current that can be detected by the second short detector 50.

As described above, the second sensing transistor M3 may be implemented as a PMOS transistor. At this time, the signal output from the error amplifier 35 of the LDO regulator 30 is applied to the gate terminal of the PMOS transistor M3, and the output voltage V _M of the DC-DC converter 20 is applied to the source terminal. .

The second resistor R _S 2 is connected to the drain terminal of the second sensing transistor M3 to convert the driving current I _SH 3 sensed by the second sensing transistor M3 into a second voltage V _Rs 2. Let's do it. At this time, the second resistance a second voltage according to the magnitude of the (R _S 2) (V _Rs 2) the value is so different, the second resistor to change the size of the (R _S 2) detected by the second short detection portion 50 It is possible to adjust the level of the drive current.

As described above, the ratio of the pass transistor M0 and the second sensing transistor M3 and the size of the second resistor R _S 2 may be changed to detect the second short detector 50. The level of the drive current can be adjusted. Accordingly, it is possible to detect that the driving current exceeds the maximum driving current due to the short current generated due to the fine short.

Meanwhile, the second comparator 53 compares the second voltage V _Rs 2 converted by the second resistor R _S 2 with the second reference voltage V _ref 2 and outputs a short detection signal.

The second comparator 53 includes the DC-DC converter 20 until the second voltage V _Rs 2 converted by the second resistor R _S 2 becomes greater than the second reference voltage V _ref 2. Outputs a short detection signal of a low level to the PWM controller 25, and the second voltage V _Rs 2 converted by the second resistor R _S 2 becomes greater than the second reference voltage V _ref 2, or When the same, the high level short detection signal is output to the PWM controller 25 of the DC-DC converter 20.

Accordingly, the PWM controller 25 receiving the low level short detection signal from the second comparator 53 generates a PWM control signal and applies it to a switch transistor (not shown), thereby displaying it in the DC-DC converter 20. When the power is supplied to the panel 60 and the high level short detection signal is applied from the second comparator 53, the DC-DC converter is not generated by generating the PWM control signal output to the switch transistor (not shown). The power is not applied to the display panel 60 at 20.

On the other hand, the second short detection unit 50 in order to ensure that the voltage across the drain terminal of the pass transistor (M0) and the drain terminal of the second sensing transistor (M3) is the same voltage, the second operational amplifier 55 and the second. It may further comprise a transistor (M4).

The voltage applied to the drain terminal of the pass transistor M0 is input to the non-inverting input terminal (+) of the second operational amplifier 55 described above, and the drain of the second sensing transistor M3 is input to the inverting input terminal (-). The voltage across the terminal is input.

The second transistor M4 is implemented between the second sensing transistor M3 and the second resistor R _S 2, and according to the output voltage of the second operational amplifier 55 input through the gate terminal. The driving current I _SH 3 output from the sensing transistor M3 is input through the source terminal and output to the second resistor R _S 2.

3 and 4 exemplarily illustrate a timing diagram according to an operation of a driving apparatus of a display panel according to an exemplary embodiment.

First, as shown in FIG. 3, when the display panel 60 is enabled according to the display panel driving signal (a), image data is applied to the display panel 60, and a predetermined time before the image data is applied. (E.g., 16 ms) black data is applied (b). Here, when the display panel 60 is normal during the black data period to which black data is applied, no current flows to the display panel 60. However, when a crack occurs in the display panel 60 and the power sources ELVDD and ELVSS are shorted, a short current flows in the display panel 60 during the black data period.

Accordingly, in order to detect the short current, after the soft start operation (c), the first short detection unit 40 is enabled from the time point when the ELVDD is stabilized (e).

As described above, when the first short detector 40 is enabled during the black data period, the first short detector 40 is shorted when the power ELVDD and the ELVSS are shorted due to a crack occurring in the display panel 60. The current flowing from the DC-DC converter 20 to the display panel 60 is sensed.

That is, when the first short detector 40 is enabled, the first sensing transistor M1 of the first short detector 40 detects a short current flowing through the pass transistor M0 of the LDO regulator 30. do.

In this case, when no crack occurs in the display panel 60, a short current does not flow from the DC-DC converter 20 to the display panel 60.

As such, when no current flows from the DC-DC converter 20 to the display panel 60, the first voltage V _Rs 1 applied to the non-inverting input terminal (+) of the first comparator 43 is set to zero. The low level short is shortened to the PWM controller 25 of the DC-DC converter 20 by being smaller than the reference voltage (V _ref 1: for example, 0.6V) applied to the inverting input terminal (-) of the comparator 43. Output the sense signal.

The PWM controller 25 receiving the low level short detection signal from the first short detection unit 40 generates a PWM control signal and applies it to a switch transistor (not shown), whereby the display panel in the DC-DC converter 20 is applied. Apply power to (60).

On the other hand, when a crack occurs in the display panel 60, a short current flows from the DC-DC converter 20 to the display panel 60.

As such, when a short current flows from the DC-DC converter 20 to the display panel 60, the short current I _SH 1 flows through the pass transistor M0 of the LDO regulator 30. Like the M0, the output signal of the error amplifier 35 is connected to the gate terminal, and the short current (M1) is also connected to the first sensing transistor M1 to which the output voltage V _M of the DC-DC converter 20 is connected to the source terminal. I _SH 2) flows.

In this case, the magnitudes of the short current I _SH 1 flowing through the pass transistor M0 and the short current I _SH 2 flowing through the first sensing transistor M1 are the pass transistor M0 and the first sensing transistor M1. The ratio of the pass transistor M0 and the first sensing transistor M1 is 100: 1, for example, when the ratio of the pass transistor M0 is 100: 1. When the current I _SH 1 flows, a 1 mA short current I _SH 2 flows through the first sensing transistor M1.

As described above, the short current I _SH 2 flowing through the first sensing transistor M1 is converted into the first voltage V _Rs 1 by the first resistor R _S 1 to thereby compare the first comparator 43. Is applied to the non-inverting input terminal (+) of FIG. 3, the first voltage V _Rs 1 converted by the first resistor R _S 1 is inverted in the first comparator 43 as shown in FIG. When the value becomes greater than or equal to the first reference voltage V _ref 1 connected to the input terminal (−), a high level short is generated by the PWM controller 25 of the DC-DC converter 20 as shown in FIG. Output the sense signal.

The PWM controller 25 receiving the high level short detection signal from the first short detection unit 40 does not generate a PWM control signal applied to a switch transistor (not shown), thereby providing a DC-DC converter 20. The power is not applied to the display panel 60.

Meanwhile, as shown in FIG. 4, when the display panel 60 is enabled according to the display panel driving signal (a), black data is applied for a predetermined time (eg, 16 ms) to the display panel 60. Image data is then applied (b).

Here, after the soft start operation (c) to detect the crack generated in the display panel 60 during the black data period, the first short detection unit 40 is enabled from the time when the ELVDD is stabilized (e).

As described above, when the first short detector 40 is enabled during the black data period, the first sensing transistor M1 of the first short detector 40 is the pass transistor M0 of the LDO regulator 30. When the display panel 60 is normal, the short current cannot be detected when the display panel 60 is normal (f), and the low level short detection signal is transmitted to the PWM controller 25 of the DC-DC converter 20. Output (g).

On the other hand, after the black data is applied to the display panel 60 for a predetermined time (b), the image data is applied (b), if the display panel 60 is normal during the image data section is applied, the display panel At 60, a current less than or equal to the maximum drive current flows. However, when a crack occurs in the display panel 60 during the operation of the display panel 60 and the power sources ELVDD and ELVSS are shorted, a current exceeding the maximum driving current flows to the display panel 60.

Accordingly, in order to detect whether the driving current applied to the display panel 60 exceeds the maximum driving current, the second short detection unit 50 is enabled after the image data starts to be applied to the display panel 60. (H).

As described above, the second short detector 50 enabled during the image data period is short-circuited with the power supply ELVDD and ELVSS due to a crack occurring in the display panel 60, and the DC-DC converter 20 due to the short current. When the driving current flowing to the display panel 60 exceeds the maximum driving current is detected.

That is, when the second short detector 50 is enabled, the second sensing transistor M3 of the second short detector 50 detects the driving current flowing through the pass transistor M0 of the LDO regulator 30. do.

In this case, when no crack occurs in the display panel 60, a driving current within the normal range flows from the DC-DC converter 20 to the display panel 60. That is, the drive current does not exceed the maximum drive current flows.

As described above, when a driving current within the normal range not exceeding the maximum driving current flows from the DC-DC converter 20 to the display panel 60, it is applied to the non-inverting input terminal (+) of the second comparator 53. The second voltage V _Rs 2 is smaller than the second reference voltage V _ref 2 applied to the inverting input terminal (−) of the second comparator 53 so that the PWM controller 25 of the DC-DC converter 20 is provided. Outputs a low level short sense signal.

The PWM controller 25 receiving the low level short detection signal from the second short detection unit 50 generates a PWM control signal and applies it to a switch transistor (not shown), thereby displaying the display panel in the DC-DC converter 20. Apply power to (60).

On the other hand, when a crack occurs in the display panel 60, a driving current exceeding the maximum driving current flows from the DC-DC converter 20 to the display panel 60 due to the short current.

As such, when a driving current exceeding the maximum driving current flows from the DC-DC converter 20 to the display panel 60, the driving current exceeding the maximum driving current is passed to the pass transistor M0 of the LDO regulator 30. I _SH 1) flows, like the pass transistor M0, the output signal of the error amplifier 35 is connected to the gate terminal, and the output voltage V _M of the DC-DC converter 20 is connected to the source terminal. The driving current I _SH 3 that exceeds the maximum driving current also flows through the second sensing transistor M3.

In this case, the magnitudes of the driving current I _SH 1 flowing through the pass transistor M0 and the driving current I _SH 3 flowing through the second sensing transistor M3 are the pass transistor M0 and the second sensing transistor M3. Drive ratio of 100 mA to the pass transistor M0 when the ratio of the pass transistor M0 and the second sensing transistor M3 is, for example, 100: 1. When the current I _SH 1 flows, a driving current I _SH 3 of 1 mA flows through the second sensing transistor M3.

As described above, the driving current I _SH 3 flowing through the second sensing transistor M3 is converted into the second voltage V _Rs 2 by the second resistor R _S 2, so that the second comparator 53 is used. Is applied to the non-inverting input terminal (+) of FIG. 4, the second voltage V _Rs 2 converted by the second resistor R _S 2 is inverted in the second comparator 53 as shown in FIG. When the voltage is greater than or equal to the second reference voltage V _ref 2 connected to the input terminal (−), a high level short is generated by the PWM controller 25 of the DC-DC converter 20 as shown in FIG. Output the sense signal.

The PWM controller 25 receiving the high level short detection signal from the second short detection unit 50 does not generate a PWM control signal applied to a switch transistor (not shown), thereby providing a DC-DC converter 20. The power is not applied to the display panel 60.

As described above, the driving apparatus of the display panel according to the present invention enables the first short detector 40 to detect a short current due to a crack generated in the display panel 60 during the black data period, The power applied to the display panel 60 from the DC-DC converter 20 is controlled according to the detection result to prevent the display panel, the DC-DC converter, the inductor, etc. from overheating.

During the image data period, a driving current applied from the DC-DC converter 20 to the display panel 60 due to a crack generated while driving the display panel 60 by enabling the second short detection unit 50 is generated. It detects whether the maximum drive current is exceeded and controls the power applied from the DC-DC converter 20 to the display panel 60 according to the detection result to prevent the display panel, the DC-DC converter, the inductor, etc. from overheating. .

On the other hand, even if the DC-DC converter 20 can apply up to 200 mA, for example, to the display panel 60, a current of up to 120 mA must be applied to the display panel 60 by the inductor size value or the characteristics of the external components. Inductors or external components can sometimes operate normally. In this case, the second short detection unit 50 is enabled during the image data period, and it is determined whether the driving current applied from the DC-DC converter 20 to the display panel 60 exceeds the maximum driving current due to the surrounding environment. By sensing and controlling the power applied from the DC-DC converter 20 to the display panel 60 according to the detection result, the over-current does not flow to the inductor or external components, thereby inductor, external components, DC-DC converter 20 Protect your back.

The driving device of the display panel of the present invention is not limited to the above-described embodiments, and may be modified in various ways within the scope of the technical idea of the present invention.

10. power supply, 20. DC-DC converter,
25. PWM controller, 30. LDO regulator,
35. error amplifier, 40. first short detector,
43. first comparator, 45. first operational amplifier
50. second short detector, 53. second comparator,
55. Secondary operational amplifier, 60. Display panel,
M0. Pass transistor, M1. A first sensing transistor,
M2. 1st transistor, M3. Second sensing transistor,
M4. 2nd transistor, R _S 1. 1st resistor,
R _S 2. Second resistance

Claims (9)

A display panel;
A DC-DC converter for boosting and outputting a constant voltage supplied from a power supply unit to a driving voltage of the display panel;
A low drop output (LDO) regulator for stepping down the output voltage of the DC-DC converter to supply the display panel;
A signal output from the error amplifier of the LDO regulator is applied to a gate terminal, and a sensing transistor to which an output voltage of the DC-DC converter is applied to a gate terminal and a drain terminal of the sensing transistor are sensed by the sensing transistor. And a comparator for converting a driving current into a voltage and a comparator for outputting a short detection signal by comparing the voltage converted by the resistor with a reference voltage. Able to detect whether a short occurs by detecting whether a drive current applied to the display panel exceeds the maximum drive current through the LDO regulator, and outputs a short detection signal to the DC-DC converter depending on whether a short occurs. The output voltage of the DC-DC converter A driving apparatus of a display panel comprising parts of the short detection.
The sensing transistor of claim 1, wherein the sensing transistor comprises:
And a driving ratio of the pass transistor of the LDO regulator to N: 1, and senses a driving current flowing through the pass transistor.
The method of claim 2, wherein the sensing transistor,
A driving device of a display panel, characterized in that implemented by a PMOS transistor.
The method of claim 2, wherein the comparator,
And outputting a low level short detection signal to a PWM controller of the DC-DC converter until the voltage converted by the resistor is greater than a reference voltage.
The display panel as claimed in claim 2, wherein the level of the driving current detectable by the short detector is adjusted by changing at least one of a ratio between the pass transistor and the sensing transistor and a magnitude of the resistance. Driving device.
The method of claim 2, further comprising an operational amplifier and a transistor such that the voltage applied to the drain terminal of the pass transistor and the drain terminal of the sensing transistor is the same voltage,
The voltage applied to the drain terminal of the pass transistor is input to the non-inverting input terminal of the operational amplifier, and the voltage applied to the drain terminal of the sensing transistor is input to the inverting input terminal.
The transistor is implemented between the sensing transistor and the resistor, and receives a short current output from the sensing transistor through a source terminal according to the output voltage of the operational amplifier input through a gate terminal to output to the resistor. A drive device for a display panel.
A display panel;
A DC-DC converter for boosting and outputting a constant voltage supplied from a power supply unit to a driving voltage of the display panel;
A low drop output (LDO) regulator for stepping down the output voltage of the DC-DC converter to supply the display panel;
A signal output from an error amplifier of the LDO regulator is applied to a gate terminal, and a first sensing transistor to which an output voltage of the DC-DC converter is applied to a source terminal and a drain terminal of the first sensing transistor are connected to the first sensing transistor. And a first comparator for converting the driving current sensed by the one sensing transistor into a voltage and a first comparator for comparing the voltage converted by the first resistor with a reference voltage and outputting a short sensing signal. Enabled during the black data period in which no current should flow through the panel, and detects a short current applied to the display panel through the LDO regulator to detect whether a short occurs, and to the DC-DC converter according to whether a short occurs. First short sense to output short sense signal to control output voltage of DC-DC converter Unit;
A signal output from the error amplifier of the LDO regulator is applied to a gate terminal, and a second sensing transistor to which an output voltage of the DC-DC converter is applied to a source terminal and a drain terminal of the second sensing transistor are connected to the second sensing transistor. And a second comparator for converting the driving current sensed by the second sensing transistor into a voltage and a second comparator for outputting a short sensing signal by comparing the voltage converted by the second resistor with a reference voltage. It is enabled during an image data period in which image data is applied to the panel, and detects whether a short occurs by detecting whether a driving current applied to the display panel through the LDO regulator exceeds a maximum driving current, and whether or not a short occurs. According to the output of the short detection signal to the DC-DC converter of the DC-DC converter And a second short detector configured to control an output voltage.
The method of claim 7, wherein the first sensing transistor of the first short detection unit,
And a short current flowing in the pass transistor of the LDO regulator and sensing a short current flowing through the pass transistor.
The method of claim 7, wherein the second sensing transistor of the second short detection unit,
And a driving ratio of the pass transistor of the LDO regulator to N: 1, and senses a driving current flowing through the pass transistor.

Images