KR20160141298A - Driver ic and display device - Google Patents

Abstract

The present invention provides a driver integrated circuit for controlling display voltage on pixels of a panel according to display data, performing an exclusive or (XOR) process on a setting value of an N^th period and a setting value of an (N+1)^th period on a first register in which a setting value is reversed with a specific period, and outputting an interrupt signal to an application processor according to a result of the XOR process. The driver integrated circuit of the present invention can detect an abnormal operation of the driver integrated circuit caused by disturbance.

Description

DRIVER IC AND DISPLAY DEVICE [0001]

The present invention relates to a display device and a driver IC for driving such a display device.

2. Description of the Related Art [0002] As an information-oriented society develops, there have been various demands for display devices for displaying images. Recently, liquid crystal displays (LCDs), plasma display panels (PDPs) Various display devices such as an OLED (Organic Light Emitting Diode Display Device) and the like are being utilized.

In order to display an image on such a display device, a driver circuit for controlling the display voltage for the pixels of the panel is required. Such a driver circuit may be implemented as a separate integrated circuit and incorporated in a display device.

On the other hand, such a driver integrated circuit may be damaged due to disturbance such as ESD (Electrostatic Discharge). Accordingly, the driver integrated circuit needs to have resistance to such a disturbance in the circuit or the device itself. Or the driver integrated circuit needs to have a protection function that can quickly respond to such disturbances and prevent further damage.

Looking more closely at the latter, a driver integrated circuit can exhibit transient response when certain disturbances are introduced. For example, when an ESD is introduced into a driver integrated circuit, there may arise a problem that a supply voltage rises due to a change in characteristics of elements. At this time, if the driver integrated circuit does not respond quickly to such disturbances, a rise in the supply voltage may cause permanent damage to other devices (for example, burn out of the resistance device or dielectric breakdown of the device with low withstand voltage) have.

In view of the foregoing, an object of the present invention is, in one aspect, to provide a technique for detecting an abnormal operation of a driver integrated circuit due to disturbance.

In another aspect, an object of the present invention is to provide a technique for preventing further damage to the driver IC by a control according to an abnormal operation detection signal.

In another aspect, an object of the present invention is to provide a technique that reduces the possibility of permanent damage of the device by minimizing the time from detection of abnormal operation to operation of the protection function.

In order to achieve the above object, in one aspect, the present invention provides a display device comprising a driver circuit for controlling a display voltage for pixels of a panel according to display data, a first register whose set value is inverted at a specific period, An XOR processing unit for XORing (exclusive or) processing the set value of the Nth cycle and the set value of the (N + 1)

And a driver integrated circuit including an interrupt pin for outputting the result of the XOR process as an interrupt signal.

According to another aspect of the present invention, there is provided a display device including a panel for displaying an image, an application processor for generating display data for controlling the image, and a display controller for controlling display voltages for the pixels of the panel according to the display data, And a set value of the (N + 1) -th cycle for the first register whose value is inverted, and outputting an interrupt signal according to the result of the XOR process to the application processor Device.

As described above, according to the present invention, it is possible to detect abnormal operation of the driver integrated circuit due to disturbance. In addition, according to the present invention, it is possible to prevent further damage to the driver IC by controlling according to the abnormal operation detection signal. In addition, according to the present invention, the time from the detection of the abnormal operation to the operation of the protection function is minimized, thereby reducing the possibility of permanent damage of the device.

1 is a view schematically showing a display device according to an embodiment.
2 is a schematic diagram of a driver integrated circuit according to one embodiment.
3 is a diagram for explaining a comparator for inputting an inverted signal to the first register.
4 is a first diagram showing waveforms of respective signals according to ESD.
5 is a diagram schematically showing a driver integrated circuit according to an example in which an XOR processing unit is implemented as an MCU.
6 is an exemplary view of a register block of the driver IC.
FIG. 7 is a diagram for explaining an example in which the XOR processing unit is implemented as a circuit.
8 is a second diagram showing waveforms of respective signals according to ESD.
9 is a signal input / output example of the power conversion apparatus.
10 is a third diagram showing waveforms of respective signals according to ESD.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected to or connected to the other component, It should be understood that an element may be "connected," "coupled," or "connected." In the same context, when an element is described as being formed on an "upper" or "lower" side of another element, the element may be formed either directly or indirectly through another element As will be understood by those skilled in the art.

1 is a view schematically showing a display device according to an embodiment.

Referring to FIG. 1, a display device 100 according to an embodiment may include a panel 110, a driver IC 120, a gate driver circuit 130, an application processor 140, and the like.

In the panel 110, a plurality of data lines are formed in a first direction (e.g., longitudinal direction or horizontal direction), a plurality of gate lines are formed in a second direction (e.g., a horizontal direction or a vertical direction) Pixels corresponding to the intersections of the lines and the plurality of gate lines may be formed.

Each pixel may have a transistor in which a source electrode or a drain electrode is connected to the data line, a gate electrode is connected to the gate line, and a drain electrode or a source electrode is connected to the pixel electrode.

The panel 110 may function only as a " display panel "or may function as a display panel and function as a" TSP (Touch Screen Panel) ".

In the panel 110, the display panel and the touch screen panel may be separated from each other by a separate film, or the display panel and the touch screen panel may be integrated into one. For example, the panel 110 may have an in-cell type in which a touch screen panel is embedded in a display panel.

When the panel 110 serves as a display panel, the driving mode of the panel 110 is referred to as a " display driving mode ", and when the panel 110 serves as a touch screen panel, Quot; touch-driving mode ".

The display driving mode and the touch driving mode may be operated in separate time periods through time division but independently of each other without time division.

The driver integrated circuit 120 may control the display voltage for the pixels of the panel according to the display data. To this end, the driver integrated circuit 120 may supply a data voltage for display purposes to a plurality of data lines.

The gate driver circuit 130 can sequentially supply the scan signals for display to the plurality of gate lines of the panel 110. [ A transistor may be formed in each pixel, which turns on this transistor so that a data voltage can be formed between the electrodes in the pixel.

1, the gate driver circuit 130 may be implemented in the driver integrated circuit 120, although the gate driver circuit 130 is illustrated as being formed of hardware separate from the driver integrated circuit 120. [

In addition, the driver integrated circuit 120 may incorporate a touch sensing circuit for sensing the proximity or touch of an object to the touch screen panel. The touch sensing circuit may receive a touch driving signal from the touch sensors of the touch screen panel and sense a reaction signal for the touch driving signal to sense proximity or touch of the object to the touch screen panel.

The driver integrated circuit 130 may send and receive data associated with driving the panel 110 or data associated with touch sensing with the application processor 140.

The application processor 140 may generate display data for controlling an image to be displayed on the panel 110 and transmit the generated display data to the driver IC 130. [ Then, when the driver integrated circuit 130 further includes a touch sensing circuit, the application processor 140 may receive data (e.g., touch coordinate data) related to touch sensing from the touch sensing circuit.

In addition, the application processor 140 accesses the registers of the driver IC 130 to obtain status information of the driver IC 130, and transmits / receives signals to obtain status information of the driver IC 130 It is possible.

On the other hand, the driver integrated circuit 130 can detect the abnormal operation of the driver integrated circuit 130 due to disturbance itself. Then, the driver integrated circuit 130 may transmit a signal sensed for the abnormal operation to an external circuit (for example, an application processor) so that the external circuit activates the protection function. An embodiment of the configurations and functions of the driver integrated circuit 130 corresponding to such a disturbance will be described in more detail with reference to FIG.

2 is a schematic diagram of a driver integrated circuit according to one embodiment.

2, the driver integrated circuit 120 may include a driver circuit 210, a first register 220, an exclusive or (XOR) processing unit 230, an interrupt pin 240, and the like.

The driver circuit 210 controls the display voltage for the pixels of the panel 110 according to the display data. For example, the driver circuit 210 may transmit the data voltages VD_1, VD_2, ..., VD_M to a plurality of data lines to control the display voltage for the pixels.

The first register 220 may be inverted to a predetermined period. For example, the first register 220 may be set to a logic high (a logic value of 1) in a first period and a logic low (a logic value of 0) in a second period. These setting values can be changed while continuously inverting every cycle. For example, the setting value of the first register 220 can be changed in the order of time while being inverted continuously as 1, 0, 1, 0,.

Here, the specific period may be a frame period for scanning an image of the panel 110, but is not limited thereto.

While the driver integrated circuit 120 is operating normally, the first register 220 may be continuously inverted at a specific period. However, if the driver integrated circuit 120 is operated abnormally, the set value of the first register 220 may have one value continuously or irregularly.

The driver integrated circuit 120 can detect the abnormal operation of the driver integrated circuit 120 by checking whether the set value of the first register 220 is periodically inverted.

The XOR processor 230 is an exemplary configuration for detecting abnormal operation of the driver IC 120 by checking whether the set value of the first register 220 is periodically inverted.

The XOR processing unit 230 can XOR (exclusive or) process the Nth (N is a natural number) period setting value and the (N + 1) th period setting value for the first register 220. [

If the set value of the Nth cycle for the first register 220 is logic high and the set value of the (N + 1) th cycle is logic low, the processing result of the XOR processing unit 230 becomes logic high. If the set value of the N-th period for the first register 220 is logic low and the set value of the (N + 1) -th period is logic high, the processing result of the XOR processing unit 230 becomes logic high.

Thus, if the first register 220 is normally inverted every cycle, the processing result of the XOR processing unit 230 becomes logic high.

On the other hand, when the set value of the Nth cycle for the first register 220 is logic high and the set value of the (N + 1) th cycle is logic high, the processing result of the XOR processing unit 230 becomes logic low. If the set value of the Nth cycle for the first register 220 is logic low and the set value of the (N + 1) th cycle is logic low, the processing result of the XOR processing unit 230 becomes logic low.

Thus, if the first register 220 is not normally inverted every cycle, the processing result of the XOR processing unit 230 becomes logic low.

The driver integrated circuit 120 can detect the abnormal operation of the driver integrated circuit 120 itself through the processing result of the XOR processing unit 230. For example, if the processing result of the XOR processing unit 120 is logic high The driver integrated circuit 120 is determined to be operating normally, and if it is logic low, the driver integrated circuit 120 may be determined to operate abnormally.

The driver integrated circuit 120 itself can sense an abnormal operation of the driver integrated circuit 120 and transmit a signal corresponding to the detection to the external circuit.

For example, the driver IC 120 may output the XOR processing result of the XOR processor 230 through the interrupt pin 240 as an interrupt signal S_INT.

3 is a diagram for explaining a comparator for inputting an inverted signal to the first register.

Driver integrated circuit 120 may further include a comparator 310 for inputting an inverted signal to the first laser.

3, the reference voltage VREF is input to the first terminal 324 and the first comparison voltage VCP_1 and the second comparison voltage VCV_2 are input to the second terminal 322 of the comparator 310, Can be alternately input.

For example, the driver integrated circuit 120 may generate an input voltage VIN in which the first comparison voltage VCP_1 and the second comparison voltage VCV_2 appear alternately in a specific period. The driver integrated circuit 120 may then input the input voltage VIN to the second terminal 322 of the comparator 310. [

Here, the first comparison voltage VCP_1 may be a voltage that is larger than the reference voltage VREF, and the second comparison voltage VCP_2 may be a voltage that is smaller than the reference voltage VREF.

The comparator 310 compares the input voltage VIN with the reference voltage VREF and outputs the output voltage VOUT. The comparator 310 outputs a logic high L HIGH if the input voltage V IN is greater than the reference voltage V REF and outputs a logic low L LOW when the input voltage V IN is less than the reference voltage V REF .

Here, the first comparison voltage VCP_1 and the second comparison voltage VCV_2 are alternately input in a specific period, and when the first comparison voltage VCP_1 is greater than the reference voltage VREF and the second comparison voltage VCP_2 is higher than the reference voltage VCP_2, (VREF), the comparator 310 alternately outputs logic high (L_HIGH) and logic low (L_LOW) in a specific period.

The set value of the first register 220 may be determined according to the output voltage VOUT of the comparator 310. For example, if the output voltage VOUT of the comparator 310 is logic high L_HIGH, the first register 220 is set to 1, and if the output voltage VOUT of the comparator 310 is logic low L_LOW The first register 220 may be set to zero. Here, the logic high L_HIGH and the set value 1 of the first register 220 may be the same voltage level, and the logic low L_LOW and the set value 0 of the first register 220 may be the same voltage level.

The first comparison voltage VCP_1 and the second comparison voltage VCP_2 may be an analog power supply voltage of the driver IC 120 and may be a logic power supply voltage or an input / output (IO) power supply voltage. For example, the first comparison voltage VCP_1 may be a positive analog power supply voltage VSP that supplies positive analog power for driving the panel 110, and the second comparison voltage VCP_2 may be a positive analog power supply voltage VSP, May be a negative analog power supply voltage (VSN) that supplies negative analog power for driving the panel 110. [ Alternatively, the first comparison voltage VCP_1 and the second comparison voltage VCP_2 are supplied to the driver IC 120 through the logic power supply voltage VDD for supplying logic power and the input / output (IO) power supply voltage (VDDIO).

The first comparison voltage VCP_1 and the second comparison voltage VCP_2 may be voltages that are integrated and supplied to the panel 110. [ For example, the first comparison voltage VCP_1 may be the gate high voltage VGH that turns on the transistor corresponding to the pixels, and the second comparison voltage VCP_2 may be the gate low voltage VGL ). The first comparison voltage VCP_1 and the second comparison voltage VCP_2 may be the data voltage VData supplied to the data line or the common voltage Vcom supplied to the common electrode.

The first comparison voltage VCP_1 and the second comparison voltage VCP_2 may be any combination of the above-described examples. Two voltages having different sizes as the voltage used in the driver integrated circuit 120 may be used as the first comparison voltage VCP_1 and the second comparison voltage VCP_2.

When the voltage used in the driver integrated circuit 120 is used as the first comparison voltage VCP_1 and the second comparison voltage VCP_2 in this manner, the comparator 310 compares the normal operation of the driver IC 120 with the abnormal operation Each can output a different output voltage (VOUT). For example, when the driver integrated circuit 120 is normally operated, the voltage used by the driver integrated circuit 120 also becomes a normal voltage. Accordingly, the first comparison voltage VCP_1 and the second comparison voltage VCP_2 are normally input to the comparator 310 and the comparator 310 can alternately output the logic high LHIGH and the logic low L_LOW . On the other hand, when the driver integrated circuit 120 is abnormally operated, the voltage used by the driver integrated circuit 120 may also become an abnormal voltage. Accordingly, the first comparison voltage VCP_1 and the second comparison voltage VCP_2 are abnormally input to the comparator 310 and the comparator 310 can not output the logic high LHIGH and the logic low L_LOW alternately . In this case, the set value of the first register 220 is not inverted normally, and the processing result of the XOR processing unit 230 may indicate that the driver IC 120 is abnormal operation.

4 is a first diagram showing waveforms of respective signals according to ESD.

Driver integrated circuit 120 may generate or receive a synchronization signal VSYNC corresponding to a frame period for scanning an image of panel 110. [

The first register 220 can be inverted in the frame period corresponding to the synchronization signal VSYNC.

Referring to FIG. 4, the set value REG1 of the first register 220 in the (N-2) th cycle represents a logic low, and the set value REG1 of the first register 220 in the (N-1) Respectively. In the Nth cycle, the set value REG1 of the first register 220 indicates a logic low, and the set value REG1 is inverted for each cycle. On the other hand, in the (N + 1) th cycle in which the ESD is introduced, the set value REG1 of the first register 220 can not be inverted from the set value REG1 of the immediately preceding period and continues to indicate a logic low.

The XOR processing unit 230 may XOR the set value REG1 of the first register 220 of the immediately preceding cycle and the previous cycle in each cycle and output the processing result XOR_OUT.

Referring to FIG. 4, in the Nth period, the XOR processing unit 230 receives the set value REG1 of the first register 220 of the (N-1) -th period and the set value REG1 of the first register 220 of the (REG1) and outputs a logic high as a processing result (XOR_OUT). The XOR processor 230 sets the set value REG1 of the first register 220 in the N period and the set value REG1 of the first register 220 in the Nth cycle in the N + XOR processing and outputs a logic high as a processing result (XOR_OUT). The XOR processing unit 230 sets the set value REG1 of the first register 220 and the set value REG1 of the first register 220 in the Nth cycle in the N + XOR processing and outputs the processing result (XOR_OUT). However, since ESD is inputted to the driver IC 120 in the (N + 1) th cycle and the set value REG1 of the first register 220 is not inverted normally, the processing result XOR_OUT of the XOR processor 230 is To a logic low. Here, the XOR processing unit 230 performs the XOR processing on the set value REG1 of the first register 220 in the immediately preceding cycle and the full cycle in each cycle. However, the XOR processing unit 230 may perform the XOR processing on the current cycle and the immediately preceding cycle The set value REG1 of the first register 220 of the period may be XORed.

On the other hand, the interrupt pin can sequentially reduce the interrupt signal S_INT from the high voltage to the low voltage in accordance with the XOR processing result (XOR_OUT).

The XOR processing unit 230 may be implemented as a digital processor. For example, the driver integrated circuit 120 may further include a touch sensing circuit that senses a touch to the panel 110. At this time, the touch sensing circuit may include a microcomputing unit (MCU), and the XOR processing unit 230 may be implemented as a processing procedure of the MCU.

5 is a diagram schematically showing a driver integrated circuit according to an example in which an XOR processing unit is implemented as an MCU.

The driver integrated circuit 120 may include an MCU 230a for touch sensing and the MCU 230a may function as the XOR processing unit 230 shown in FIG.

The MCU 230a reads the set value of the first register 220 and stores the set value in the memory every predetermined period. The set value of the first register 220 stored in the Nth cycle and the set value of the first register 220 stored in the The set value of the read first register 220 can be XORed.

If the MCU 230a additionally includes a function for touch detection, the driver integrated circuit 120 may transmit an attention signal Attn to the application processor 140 according to the touch detection. To this end, the driver integrated circuit 120 may include an attitude signal pin, which may use the attitude signal pin as the interrupt pin 240 described above. In this case, the touch sensing circuit (not shown) including the MCU 230a may output the attention signal Attn to the interrupt pin 240 when a touch to the panel 110 is sensed.

At this time, the attention signal Attn output by the touch sensing circuit (not shown) through the interrupt pin 240 may be the same signal as the above-described interrupt signal S_INT. In other words, a touch sensing circuit (not shown) may output an interrupt signal (S_INT) to the interrupt pin 240 when a touch to the panel 110 is sensed.

The application processor 140 may receive the attention signal Attn and the interrupt signal S_INT from the driver IC 120 and may perform a response procedure corresponding to each signal. As described above, the application processor 140 receives the attention signal Attn and the interrupt signal S_INT, If the signal S_INT is the same signal, it may be a problem to distinguish it in the application processor 140.

On the other hand, this problem can be solved by the application processor 140 reading the set values of the registers of the driver integrated circuit 120. [

6 is an exemplary view of a register block of the driver IC.

The driver integrated circuit 120 may include a register block 620 that includes a plurality of registers.

Referring to FIG. 6, a first register 220 and a second register 222 may be located in the register block 620.

The driver integrated circuit 120 may output an interrupt signal (S_INT) to the application processor 140 via the interrupt pin 240. At this time, the driver integrated circuit 120 may change the setting values of some registers or all registers located in the register block 620 together with the output of the interrupt signal S_INT or before the output of the interrupt signal S_INT. For example, the driver integrated circuit 120 may output an interrupt signal (S_INT) via an interrupt pin (240) when a touch is sensed. The interrupt signal (S_INT) may be output together with the output of the interrupt signal The setting value of the second register 222 may be changed to 1. [

The application processor 140 reads the set value of the second register 222 according to the interrupt signal S_INT and sets the interrupt signal S_INT to the attitude detection signal S_INT when the set value of the second register 222 is 1 Attn) can be interpreted as. Thus, even if the same interrupt signal S_INT is output using the same interrupt pin 240, the application processor 140 can read the register values of the register block 620 and classify the function of the interrupt signal S_INT .

Meanwhile, the XOR processing unit 230 may be implemented as a circuit.

FIG. 7 is a diagram for explaining an example in which the XOR processing unit is implemented as a circuit.

In order to XOR the set value REG1 (N) of the first register 220 in the Nth cycle and the set value REG1 (N + 1) of the first register 220 in the (N + 1) The set value of the 1 register 220 may be copied to the third register and stored before the set value is changed according to the (N + 1) th cycle. The third register may be referred to as a copy register.

The XOR processing unit 230 can XOR the set value REG3 (N + 1) of the copy register and the set value REG1 (N + 1) of the first register 220. [

Referring to FIG. 7, the current cycle setting value REG1 (N) of the first register 220 may be copied to the copy register when the current cycle is the (N + 1) -th cycle.

The XOR processing unit 230 may include an XOR logical operation circuit 230b and the set value REG3 (N + 1) of the copy register and the first register 220, (REG1 (N + 1)) can be input. The XOR logical operation circuit 230b XORs the set value REG3 (N + 1) of the copy register with the set value REG1 (N + 1) of the first register 220 and outputs the result XOR_OUT Can be output.

The abnormal operation of the driver integrated circuit 120 may be detected according to one embodiment. The driver integrated circuit 120 may itself detect this abnormal operation and may also transmit such detection to the interrupt signal S_INT to enable external devices to detect abnormal operation of the driver integrated circuit 120 have.

On the other hand, in response to the abnormal operation detection of the driver integrated circuit 120, the driver integrated circuit 120 or the external device (for example, the application processor 140) can activate the protection function to prevent further damage . An example of such a protection function will be described in more detail.

The application processor 140 may stop supplying some or all of the voltages supplied to the driver integrated circuit 120 according to the interrupt signal S_INT. In this way, the application processor 140 can prevent further damage to the driver IC 120. [ Further, the voltage supplied to the panel 110 may be cut off to prevent further damage to the panel 110.

8 is a second diagram showing waveforms of respective signals according to ESD.

Referring to FIG. 8, the set value REG1 of the first register 220 is inverted according to the synchronization signal VSYNC corresponding to the frame period. In accordance with the ESD input in the (N + 1) Is not normally inverted.

At this time, the processing result (XOR_OUT) of the XOR processing unit 230 is changed to a logic low in accordance with the abnormality of the set value REG1 of the first register 220. [ Then, according to the processing result (XOR_OUT) of the XOR processing unit 230, the interrupt signal S_INT can be changed from a first state (e.g., a high voltage) to a second state (e.g., a low voltage) . 8 shows that the first state of the interrupt signal S_INT is a high voltage and the second state is a low voltage. Conversely, when the first state of the interrupt signal S_INT is a low voltage and the second state is a high voltage Lt; / RTI >

The application processor 140 recognizes that the output of the interrupt pin 240 of the driver integrated circuit 120 is changed from the first state to the second state and then stops supplying the voltage supplied to the driver integrated circuit 120 .

8, the application processor 140 recognizes a change in the state of the interrupt signal S_INT and generates a negative analog power supply voltage VSP supplied to the driver IC 120, ), The logic power supply voltage VDD and the input / output (IO) power supply voltage VDDIO.

When the interrupt signal S_INT is used in common with the attention signal Attn as described above, the application processor 140 recognizes that the output of the interrupt pin 240 changes from the first state to the second state The set value of the first register 220 may be read and the supply voltage may be stopped when the set value of the first register 220 is the first logic value.

Here, the application processor 140 can predict the set value of the first register 220 every cycle. When the first logic value is a value different from this prediction, the application processor 140 controls the driver integrated circuit 120, And thus interrupt the supply voltage. On the other hand, when the set value of the first register 220 matches the predicted value with the second logic value, the application processor 140 recognizes the interrupt signal S_INT as the attention signal Attn according to the touch detection, (E.g., touch coordinate information) with respect to the panel 110 from the touch panel 120.

On the other hand, the driver integrated circuit 120 can detect an abnormal operation and activate the protection function by itself.

For example, the driver integrated circuit 120 may include a power conversion device that converts a first voltage supplied from the outside to a second voltage, and stops the operation of the power conversion device, Some functions may be interrupted.

9 is a signal input / output example of the power conversion apparatus.

The driver integrated circuit 120 may include a power inverter 910 for converting a first voltage V1 supplied from the outside to a second voltage V2. The power conversion apparatus 910 may stop the operation according to the processing result (XOR_OUT) of the XOR processing unit 230, thereby preventing the second voltage V2 from being output.

The first voltage V1 may be, for example, one of a positive analog power supply voltage VSP, a negative analog power supply voltage VSN, a logic power supply voltage VDD and an input / output (IO) power supply voltage VDDIO Lt; / RTI >

The second voltage V2 may be, for example, a gate high voltage VGH, a gate low voltage VGL, a data voltage VData or a common voltage Vcom.

10 is a third diagram showing waveforms of respective signals according to ESD.

Referring to FIG. 10, the set value REG1 of the first register 220 is inverted according to the synchronization signal VSYNC corresponding to the frame period. In accordance with the ESD flowing in the (N + 1) Is not normally inverted.

At this time, the processing result (XOR_OUT) of the XOR processing unit 230 is changed to a logic low in accordance with the abnormality of the set value REG1 of the first register 220. [ Then, according to the processing result (XOR_OUT) of the XOR processing unit 230, the interrupt signal S_INT can be changed from a first state (e.g., a high voltage) to a second state (e.g., a low voltage) .

The power conversion apparatus 910 is connected to the gate high voltage VGH, the gate low voltage VGL, the data voltage VData, or the common voltage VSS in accordance with the processing result XOR_OUT of the XOR processing unit 230 or according to the interrupt signal S_INT. The generation of the voltage Vcom can be stopped.

As such, the driver IC 120 or the display device 100 according to an exemplary embodiment may perform additional damage to the driver IC 120, the panel 110, or the display device 100 by controlling according to the abnormal operation detection signal. There is an effect that can be prevented. In addition, according to one embodiment, since the interrupt signal S_INT is generated in the driver integrated circuit 120 immediately upon detection of the abnormal operation, and the driver integrated circuit 120 or the display device 100 activates the protection function , The time to the operation of the protection function can be minimized and the possibility of permanent damage of the device can be reduced.

It is to be understood that the terms "comprises", "comprising", or "having" as used in the foregoing description mean that the constituent element can be implanted unless specifically stated to the contrary, But should be construed as further including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Claims (15)

A driver circuit for controlling a display voltage for the pixels of the panel according to the display data;
A first register whose set value is inverted at a specific cycle;
An XOR processor for XORing a set value of the Nth (N is a natural number) period and a set value of the (N + 1) th period for the first register; And
An interrupt pin for outputting the result of the XOR process as an interrupt signal
≪ / RTI > The method according to claim 1,
Further comprising a comparator in which a reference voltage is input to the first terminal and a first comparison voltage and a second comparison voltage are alternately input to the second terminal at the specific period,
And a set value of the first register is determined according to an output of the comparator. The method according to claim 1,
Wherein the first comparison voltage is a gate high voltage that turns on the transistor corresponding to the pixels and the second comparison voltage is a gate low voltage that turns off the transistor. The method according to claim 1,
Further comprising a touch sensing circuit for sensing a touch to the panel,
Wherein the touch sensing circuit outputs the interrupt signal to the interrupt pin when a touch to the panel is sensed. 5. The method of claim 4,
And a second register in which a set value is changed according to the touch sensing circuit,
And the application processor reads the set value of the second register according to the interrupt signal. The method according to claim 1,
Further comprising a power conversion circuit for converting a first voltage supplied from the outside into a second voltage for driving the display,
And the operation of the power conversion circuit is turned off according to the result of the XOR process. The method according to claim 1,
And the supply of the first voltage from the outside is stopped according to the interrupt signal. The method according to claim 1,
The XOR processing unit,
Wherein the setting value of the first register stored in the Nth period and the setting value of the first register read in the Nth period are stored in the memory, Is subjected to XOR processing. The method according to claim 1,
Further comprising a copy register for copying and storing the previous cycle set value of the first register,
The XOR processing unit,
And XORs the set value of the copy register and the set value of the first register. The method according to claim 1,
Wherein the specific period is a frame period for scanning an image of the panel. A panel for displaying an image;
An application processor for generating display data for controlling the image; And
(N is a natural number) period and a set value of an (N + 1) -th period for a first register in which a set value is inverted at a specific period according to the display data, And outputting an interrupt signal according to a result of the XOR process to the application processor. 12. The method of claim 11,
The application processor
And stops supply of the first voltage to the driver integrated circuit in accordance with the interrupt signal. 13. The method of claim 12,
Wherein the driver integrated circuit includes an interrupt pin for outputting the interrupt signal,
Wherein the application processor stops the first voltage supply after recognizing that the output of the interrupt pin is changed from the first state to the second state. 14. The method of claim 13,
Wherein the application processor recognizes that the output of the interrupt pin is changed from the first state to the second state and then reads the set value of the first register and when the set value of the first register is the first logic value, And the voltage supply is stopped. 14. The method of claim 13,
The application processor recognizes that the output of the interrupt pin is changed from the first state to the second state and then reads the set value of the first register and when the set value of the first register is the second logic value, And receives touch information on the panel from the circuit.

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