KR102509845B1 - Display device and driving method thereof - Google Patents

Abstract

An object of the present invention is to provide a display device that reduces errors in main link data (Main Link) by changing a swing width of the main link data (Main Link). A display device according to the present invention includes a display panel, a data driver outputting a data voltage to the display panel, and a timing controller receiving main link data from an external system and outputting image data to the data driver, wherein the timing controller analyzes errors in the main link data and modulates the swing width of the main link data.

Description

Display device and its driving method {DISPLAY DEVICE AND DRIVING METHOD THEREOF}

The present invention relates to a display device, and more particularly, to a display device capable of modulating a swing width of main link data and a method for driving the same.

Flat Panel Display (FPD) replaces the conventional Cathode Ray Tube (CRT) display device to reduce the size and weight of not only desktop computer monitors, but also portable computers such as notebook computers and PDAs and mobile phone terminals. It is an essential display device to implement the system.

Currently commercialized flat panel display devices include liquid crystal displays (LCDs), organic light emitting diodes (OLEDs), and the like. The liquid crystal display device has advantages such as excellent visibility, easy thinning, and low power consumption, and the organic light emitting device has advantages such as a wide viewing angle, excellent contrast ratio, fast response speed, and low power consumption.

1 is a diagram showing a timing control unit of a conventional display device.

As shown in FIG. 1, the timing control unit 10 includes a receiving unit 11 for receiving main link data (Main Link), an error checking unit 12 for checking an error in the received main link data (Main Link), and the It includes an initialization controller 13 that initializes an error in main link data (Main Link) and a transmitter 14 that outputs image data (RGB).

The receiving unit 11 receives main link data (Main Link) input from an external system (not shown) and outputs it to the error checking unit 12 in order to check errors in the main link data (Main Link). In addition, the receiving unit 11 receives driving power (not shown) for driving the timing control unit 10 as well as main link data (Main Link) and an AUX signal (not shown) for setting the interface of the timing control unit 10. can be additionally received.

2 is a diagram showing waveforms of main link data applied to a timing controller of a conventional display device.

The error checking unit 12 checks errors in main link data input from the receiving unit 11 . As shown in FIG. 2, the main link data (Main Link) can be represented by an eye-diagram, and the main link data (Main Link) swings while maintaining a certain width (W), It has an eye-pattern with a certain height (H).

The height (H) of the eye-pattern is proportional to the swing width (W) of the main link data (Main Link). When the height (H) of the eye-pattern does not exceed a certain threshold height, the error checking unit 13 recognizes this as an error in the main link data (Main Link).

The initialization control unit 13 checks the number of errors in the main link data (Main Link), and if the number of errors in the main link data (Main Link) does not exceed the allowable number of errors, the main link data for each frame. (Main Link) error initialization. In this way, an error is initialized for each frame to control the number of errors in the main link data (Main Link).

The transmission unit 14 receives error-checked main link data (Main Link), decodes it, generates image data (RGB) and various control signals (not shown), and uses a gate/data driver (not shown) output this to

Due to the output image data (RGB) and various control signals, a display panel (not shown) implements an image.

However, the display device driven by the above method has the following problems.

First, when the number of errors in the main link data (Main Link) exceeds the allowable number of errors, the initialization control unit 13 is not driven, and the main link data (Main Link) with errors are decoded as they are. ) to generate image data (RGB) with residual errors and various control signals. Therefore, a desired image is not implemented on the display panel.

Second, when an image defect is caused by an excess of the number of errors in the main link data (Main Link), it is difficult to find the cause of the image defect because there is no way to check the error in the main link data (Main Link) in the timing controller 10. has a problem.

Lastly, since the swing width (W) of the main link data (Main Link) is fixed at a certain value, an error in the main link data (Main Link) occurs and the swing width (W) of the main link data (Main Link) is changed. Although it needs to be changed, there is a problem that it cannot respond to it. In addition, there is a problem in that it cannot flexibly respond to changes in specifications of external systems.

An object of the present invention is to provide a display device that reduces errors in main link data (Main Link) by changing a swing width of the main link data (Main Link).

A display device according to the present invention includes a display panel, a data driving unit, and a timing control unit.

The data driver outputs a data voltage to the display panel.

The timing controller receives main link data from an external system, outputs video data to the data driver, analyzes an error in the main link data, and modulates a swing width of the main link data.

The number of errors in the main link data may be identified by generating an error waveform in the error waveform generator. Accordingly, when an image defect is caused by an excess of the number of errors in the main link data (Main Link), the timing control unit can check the error in the main link data (Main Link), so that the cause of the image defect can be immediately identified.

In addition, by initializing the number of errors in the main link data (Main Link) for each frame, the transmission unit decodes the error-free main link data (Main Link), and the error-free image data (RGB) and It generates various control signals. Thus, a desired image is implemented on the display panel.

In addition, by changing the swing width of the main link data (Main Link), when there is a need to change the swing width of the main link data (Main Link) according to the error occurrence and standard change of the main link data (Main Link), You can respond flexibly to this.

1 is a diagram showing a timing control unit of a conventional display device.
2 is a diagram showing waveforms of main link data applied to a timing controller of a conventional display device.
3 is a diagram illustrating a display device according to an exemplary embodiment of the present invention.
4 is a diagram illustrating a timing control unit of a display device according to an exemplary embodiment of the present invention.
FIG. 5 is a diagram illustrating an error waveform comparison unit shown in FIG. 4 .
6A is an eye diagram of main link data having a swing width of 400 mV, and FIG. 6B is a diagram showing an error waveform, a first driving signal, and a second driving signal corresponding thereto.
7A is an eye diagram of main link data having a swing width of 600 mV, and FIG. 7B is a diagram showing an error waveform, a first driving signal, and a second driving signal corresponding thereto.
8 is a flowchart illustrating a method of driving a display device according to an exemplary embodiment of the present invention.

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

3 is a diagram illustrating a display device according to an exemplary embodiment of the present invention.

As shown in FIG. 3 , the display device 100 according to an exemplary embodiment of the present invention includes a display panel 110 , gate/data drivers 123 and 125 driving the display panel 110 , and gate/data drivers 123 and 125 . It includes a timing control unit 131 for controlling.

In the display panel 110, a plurality of gate lines GL and a plurality of data lines DL are crossed in a matrix form on a substrate (not shown) using glass or plastic. Also, a plurality of pixels (not shown) are defined at intersections of the gate line GL and the data line DL. Also, a common electrode (not shown) facing the pixel electrode (not shown) of the pixel may be disposed.

Each of the plurality of pixels may include a thin film transistor (not shown) and a liquid crystal capacitor (not shown). The thin film transistor has a gate electrode connected to the gate line GL, a source electrode connected to the data line DL, and a drain electrode connected to the pixel electrode. The thin film transistor is turned on by the gate voltage provided through the gate line GL, and transfers the data voltage provided through the data line DL to the pixel electrode. In the liquid crystal capacitor, the data voltage provided to the pixel electrode through the thin film transistor and the common voltage applied to the common electrode form an electric field, and accordingly, an image is displayed by changing the arrangement of liquid crystals to adjust light transmittance.

The display device 100 according to an embodiment of the present invention will be described with a focus on a liquid crystal display, but is not limited thereto, and the display device 100 includes an organic light emitting display (OLED display), an electrophoretic display (EPD), and a plasma display device. It may be implemented based on a flat display panel such as a display panel (PDP).

4 is a diagram illustrating a timing control unit of a display device according to an exemplary embodiment of the present invention.

As shown in FIG. 4 , the timing controller 131 of the display device according to an embodiment of the present invention includes a receiver 132, an error checker 133, an error waveform generator 135, and an error waveform comparison unit 136. , an initialization control unit 137, a level control unit 138 and a transmission unit 134.

The receiver 132 receives main link data (Main Link) from a transmitter (not shown) of the external system 141 . Here, the receiving unit 132 determines whether or not a normal display is displayed through a simple pattern before receiving the main link data (Main Link), and then receives the main link data (Main Link) in earnest.

In addition, the receiver 132 may have a built-in CDR (Clock and Data Recovery) circuit. A CDR (Clock and Data Recovery) circuit restores a clock signal included in main link data from an external system 141 to generate an internal clock signal. The timing controller 131 samples data according to the timing of the internal clock signal.

The error checking unit 133 may represent the main link data received from the receiving unit 132 as an eye-diagram. The main link data (Main Link) swings while maintaining a certain width and has an eye-pattern having a certain height.

The height of the eye-pattern is proportional to the swing width of the main link data (Main Link). When the height of the eye-pattern does not exceed a certain threshold height, the error checking unit 133 detects this as an error in the main link data. The number of errors in the main link data (Main Link) recognized in this way is checked, and the number of errors in the main link data (Main Link) is output to the error waveform generator 135.

The error waveform generating unit 135 converts an error of main link data provided from the error checking unit 133 into an error waveform Er. Here, the error waveform Er may be a 10-bit digital waveform.

For example, when the number of errors in the main link data (Main Link) is 1023 or more, the error waveform generator 135 generates an error waveform (Er) in which the 10-bit digital waveform is 1111111111, and the main link data (Main Link) ) is 568, which is 1023 or less, generates an error waveform (Er) with a 10-bit digital waveform of 1000111000.

In this way, the number of errors in the main link data (Main Link) can be determined by generating the error waveform (Er) in the error waveform generator 135. Accordingly, when an image defect is caused due to an excess of the number of errors in the main link data (Main Link), the timing control unit 131 can check the error in the main link data (Main Link) and immediately grasp the cause of the image defect. can

The error waveform comparator 136 compares the error waveform Er and the reference waveform Ref, and outputs a driving signal. More specifically, the error waveform comparison unit 136 outputs the first driving signal CS1 to the level adjusting unit 138 and outputs the second driving signal CS2 to the initialization control unit 137 . Here, when the reference waveform (Ref) is based on the 10-bit error waveform (Er), it may be 1111111111, which is a high-level error waveform (Er).

FIG. 5 is a diagram illustrating an error waveform comparison unit shown in FIG. 4 .

As shown in FIG. 5, the error waveform comparator 136 includes a first exclusive OR gate XOR1 having a bubble attached to an output terminal and receiving an error waveform Er and a reference waveform Ref. It is composed of a second exclusive OR gate (XOR2) receiving an error waveform (Er) and a reference waveform (Ref) without a bubble being attached to the output terminal.

Here, a signal output from the first exclusive OR gate (XOR1) to the level controller 138 is defined as the first driving signal CS1, and a signal output from the second exclusive OR gate (XOR2) to the initialization control unit 137 is defined as the first driving signal CS1. The signal may be defined as the second driving signal CS2. The number of bits of the first driving signal CS1 and the second driving signal CS2 may be the same as the number of bits of the error waveform Er and the reference waveform Ref. For example, when the error waveform Er and the reference waveform Ref are 10-bit waveforms, the first driving signal CS1 and the second driving signal CS2 may also be 10-bit waveforms. In addition, the first driving signal CS1 and the second driving signal CS2 are output every frame to drive the level control unit 138 or the initialization control unit 137 every frame.

Since the reference waveform Ref is fixed at a high level, the outputs of the first driving signal CS1 and the second driving signal CS2 vary according to the error waveform Er. For example, when a high level error waveform Er is applied, the first drive signal CS1 is a high level and the second drive signal CS2 is a low level. Conversely, when a low-level error waveform Er is applied, the first driving signal CS1 has a low level and the second driving signal CS2 has a high level.

The initialization control unit 137 outputs a reset signal Rst to the error checking unit 133 according to the second drive signal CS2 provided from the error waveform comparison unit 136, thereby counting the number of errors in the main link data (Main Link). initialize More specifically, the initialization control unit 137 sends the error check unit 133 only when the error waveform Er is not the same as the reference waveform Ref and the second driving signal CS2 is not at a high level in all bits. It outputs a reset signal (Rst). That is, when the second drive signal CS2 is 10 bits, the error waveform Er is not the same as the reference waveform Ref, so at least one bit of 0 when the second drive signal CS2 is not 1111111111. When is output, a reset signal Rst is output.

The level control unit 138 determines the swing width of the main link data (Main Link) according to the first drive signal CS1 provided from the error waveform comparison unit 136. More specifically, the level control unit 138 generates main link data (Main Link) only when the error waveform (Er) is the same as the reference waveform (Ref) and the first drive signal (CS1) is at a high level in all bits. A modulation signal (MS) for modulating the swing width of is output.

Here, the swing width of the main link data (Main Link) may be composed of a plurality of levels. For example, the plurality of levels may be 0.4V, 0.6V, 0.8V, or 1.2V, and the error waveform Er is the same as the reference waveform Ref, so that the first driving signal CS1 has a high level in all bits. In this case, the swing width of the main link data (Main Link) is increased by one level and stored in the internal memory (not shown) included in the level adjusting unit 138. For example, when the first driving signal CS1 is at a high level, the swing width of the main link data (Main Link) increased from 0.4V to 0.6V, from 0.6V to 0.8V, and from 0.8V to 1.2V is internal. The modulation signal (MS) stored in the memory and modulated with the swing width of the increased main link data (Main Link) is output to the external system 141 through AUX communication. In addition, the external system 141 outputs main link data (Main Link) according to the swing width of the increased main link data (Main Link) in the next frame.

6A is an eye diagram of main link data having a swing width of 400 mV, and FIG. 6B is a diagram showing an error waveform, a first driving signal, and a second driving signal corresponding thereto.

As shown in FIG. 6A , main link data having a swing width of 400 mV may be received from the external system 141 . The main link data having a swing width of 400 mV has an eye-pattern having a height of 79 mV. Here, the error checking unit 133 analyzes the height of the eye-pattern and determines the number of errors in the main link data (Main Link). For example, due to the eye-pattern having a height of 79 mV, the number of errors in main link data (Main Link) of 1023 or more can be detected.

As shown in FIG. 6B, the error waveform generator 135 may convert the number of errors of the main link data (Main Link) of 1023 or more into a 10-bit high-level error waveform (Er). That is, the error waveform Er may be generated as 1111111111. When the 10-bit high-level reference waveform (Ref) and the high-level error waveform (Er) are the same, the error waveform comparator 136 generates a 10-bit high-level first driving signal CS1 and a 10-bit high-level error waveform. A low-level second driving signal CS2 may be output. The first drive signal CS1 generated in this way is output to the level adjusting unit 138 .

In addition, the level control unit 138 receives the first drive signal CS1 of the high level and stores the swing width of the main link data (Main Link) increased by one level in an internal memory. That is, the swing width of the main link data (Main Link) of 600 mV is stored, and the modulation signal (MS) is transmitted to the external system 141 through AUX communication at the start of the next frame, so that the swing of the main link data (Main Link) increase the width.

7A is an eye diagram of main link data having a swing width of 600 mV, and FIG. 7B is a diagram showing an error waveform, a first driving signal, and a second driving signal corresponding thereto.

As shown in FIG. 7A , main link data having a swing width of 600 mV may be received from the external system 141 . The main link data having a swing width of 600 mV has an eye-pattern having a height of 171 mV. Here, the error checking unit 133 analyzes the height of the eye-pattern and determines the number of errors in the main link data (Main Link). For example, due to the eye-pattern having a height of 171 mV, the number of errors in 568 main link data (Main Link) can be detected.

As shown in FIG. 7B, the error waveform generating unit 135 may convert the number of errors of the 568 pieces of main link data into a 10-bit error waveform (Er). That is, the error waveform Er may be generated as 1000111000. The error waveform comparator 136 compares the 10-bit high-level reference waveform Ref with the error waveform Er to obtain a first driving signal CS1 having a waveform of 1000111000 and a second driving signal having a waveform of 0111000111 ( CS2) can be output. The second drive signal CS2 generated in this way is output to the initialization controller 137 .

Further, the initialization control unit 137 receives the second driving signal CS2 and outputs a reset signal Rst to the error checking unit 133 to initialize the number of errors in the main link data (Main Link). In this way, by initializing the number of errors in the main link data (Main Link) for each frame, the transmission unit 134 decodes the error-free main link data (Main Link) to decode the error-free image data (RGB). ) and various control signals are generated. Accordingly, a desired image is implemented on the display panel 100 .

In addition, when there is a need to change the swing width of the main link data (Main Link) according to the occurrence of errors and standard changes of the main link data (Main Link), it can respond flexibly to this.

In addition, the timing controller 131 receives a timing signal (not shown) transmitted from the external system 141 and generates a gate control signal GCS and a data control signal DCS. The gate control signal GCS is output to the gate driver 123 and the data control signal DCS is output to the data driver 125 through the EPI wire pair. Here, the timing signal may be a data enable signal (DE), a horizontal synchronization signal (Hsync), a vertical synchronization signal (Vsync), and a clock signal (CLK). In addition, the timing controller 131 generates digital image data (RGB) from the main link data (Main Link) transmitted from the external system 141 and outputs it to the data driver 125 through the EPI wire pair. .

The gate driver 123 may sequentially output gate voltages by one horizontal period through the gate line GL in response to the gate control signal GCS provided from the timing controller 131 . Accordingly, the thin film transistors connected to each gate line GL are turned on by one horizontal period. Here, the gate driver 123 may include a plurality of shift registers (not shown) connected to a plurality of gate lines GL, and may be configured in the form of a GIP (Gate In Panel) mounted inside the display panel 110. there is.

Here, the gate control signal GCS includes a gate start pulse GSP, a gate shift clock GSC, and a gate output enable signal GOE. The gate start pulse GSP is applied to the shift register of the gate driver 123 as a signal for determining when to output a gate voltage to the first gate line GL. The gate shift clock (GSC) is commonly applied to each shift register and is a clock signal enabling the next shift register (not shown). The gate output enable signal GOE controls the output of the shift register.

The data driver 125 converts the digital image data RGB provided from the timing controller 131 through the EPI wire pair into an analog data voltage according to the data control signal DCS. And, the data driver 125 applies the analog data voltage to the pixel electrode of each pixel through the data line DL.

In addition, the data control signal (DCS) includes a source start pulse (SSP), a source shift clock (SSC) and a source output enable signal (SOE). The source start pulse SSP determines sampling start timing of the image data RGB of the data driver 125 . The source shift clock (SSC) is a clock signal that controls a data sampling operation in the data driver 125 . The source output enable signal SOE controls the output of the data driver 125.

8 is a flowchart illustrating a method of driving a display device according to an exemplary embodiment of the present invention.

First, when power (Vcc) of the display device 100 is applied, the interface between the timing controller 131 and the external system 141 starts to operate. (S110) Here, the interface may correspond to DisplayPort (DP) or High Definition Multimedia Interface (HDMI).

Then, the main link data (Main Link) of a simple pattern is output to the timing controller 131 to execute link training. (S120) Through this, it is determined whether it is a normal display (Normal Display), and if it is not a normal display (Normal Display), link training is repeated. (S130)

When a normal display is determined, main link data is transmitted. After (S140), the error checking unit 133 analyzes the eye-pattern of the main link data (Main Link), determines the case where the height of the eye-pattern is less than a certain specification, and The number of errors in the link data (Main Link) is output and transmitted to the error waveform generator 135 to generate an error waveform (Er). (S150)

The error waveform comparator 136 compares the error waveform Er and the reference waveform Ref. (S160) When the error waveform (Er) and the reference waveform (Ref) are the same, the first driving signal (CS1) of a high level is output to the level control unit 138 to adjust the swing width of the main link data (Main Link). modulate (S161)

Here, the swing width of the main link data (Main Link) may be composed of a plurality of levels. For example, the plurality of levels may be 0.4V, 0.6V, 0.8V, or 1.2V, and when the first driving signal CS1 has a high level in all bits, the internal memory included in the level adjusting unit 138 In (not shown), the swing width of the main link data (Main Link) is increased by one level and stored. For example, when the first driving signal CS1 is at a high level, the swing width of the main link data (Main Link) increased from 0.4V to 0.6V, from 0.6V to 0.8V, and from 0.8V to 1.2V is internal. The modulation signal (MS) stored in the memory and modulated with the swing width of the increased main link data (Main Link) is output to the external system 141 through AUX communication. In addition, the external system 141 outputs main link data (Main Link) according to the swing width of the increased main link data (Main Link) in the next frame.

By changing the swing width of the main link data (Main Link) in this way, when there is a need to change the swing width of the main link data (Main Link) according to the error occurrence and standard change of the main link data (Main Link), You can respond flexibly.

The error waveform comparator 136 compares the error waveform Er and the reference waveform Ref, and when the error waveform Er and the reference waveform Ref are not the same, the initialization controller 137 performs a second drive. By outputting the signal CS2, the number of errors in the main link data (Main Link) is initialized. (S162) In this way, the number of errors in the main link data (Main Link) is initialized for each frame, and the transmission unit 134 decodes the main link data (Main Link) in which the error does not remain, so that the error does not remain. Data (RGB) and various control signals are generated. Accordingly, a desired image is implemented on the display panel 100 .

Although many details have been specifically described in the foregoing description, this should be interpreted as an example of a preferred embodiment rather than limiting the scope of the invention. Therefore, the invention should not be defined according to the described examples, but should be defined according to the scope of the claims and the scope of the claims.

100: display device 110: display panel
131: timing control unit 132: receiver
133: error checking unit 134: transmission unit
135: error waveform generation unit 136: error waveform comparison unit
137: initialization control unit 138: level control unit

Claims (10)

display panel;
a data driver outputting a data voltage to the display panel; and
A timing control unit receiving main link data from an external system and outputting video data to the data driver;
The timing controller analyzes errors in the main link data and modulates the swing width of the main link data;
the timing controller
an error checking unit outputting the number of errors from the main link data;
an error waveform generator outputting an error waveform according to the number of errors;
an error waveform comparator for comparing the error waveform with a reference waveform and outputting a driving signal;
an initialization control unit outputting a reset signal to the error checking unit according to the driving signal to initialize the number of errors; and
A display device comprising a level adjusting unit outputting a modulation signal for modulating a swing width of the main link data to an external system according to the driving signal. delete According to claim 1,
When the error waveform is the same as the reference waveform,
The level control unit outputs a modulation signal for modulating the swing width of the main link data to an external system. According to claim 1,
The level control unit outputs a modulation signal that increases the swing width of the main link data by one level. According to claim 4,
The swing width level of the main link data is 0.4 V, 0.6 V, 0.8 V and 1.2 V display device. According to claim 1,
If the error waveform is not the same as the reference waveform,
wherein the initialization control unit outputs a reset signal to the error checking unit for initializing the number of errors. According to claim 1,
The error waveform comparator outputs the driving signal for each frame of the display panel. According to claim 1,
The error waveform generator outputs the error waveform as a 10-bit digital waveform. Executing link training by applying power to the timing controller;
Receiving main link data from the timing controller;
outputting the number of errors from the main link data; and
According to the number of errors in the main link data, modulating the swing width of the main link data or initializing the number of errors in an error check unit,
After the step of outputting the number of errors, further comprising generating an error waveform according to the number of errors,
Modulating the swing width of the main link data when the error waveform and the reference waveform are the same;
A method of driving a display device that initializes the number of errors in an error checking unit when the error waveform and the reference waveform are not the same. delete

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