JP2002366123A - Flat panel display device and its driving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flat panel display device, which can have display characteristics adjusted with ease without any option board, and its driving method. SOLUTION: A liquid crystal panel display module 400 transmits display characteristic information such as the digital video information and control signals of a liquid crystal panel from a memory part 430 to a graphic source part 310 through serial buses 411 and 412 and cables 311 and 312. The graphic source part 310 interprets the information and generates digital video information and control signals matching panel characteristics to display a picture. Consequently, a flat panel display module can correct and interpret the display characteristic information of a flat panel and output a display signal of a new corresponding standards.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a flat panel display device and a driving method thereof, and more particularly, to a driving device for driving a flat panel display device and a driving method thereof.

[0002]

2. Description of the Related Art As a typical flat panel display device that is commercially available, a liquid crystal display device (LCD) is known.
Display) and Plasma Display (PDP)
Panel) and EL (Electro Luminescen)
ce) Development of display devices and the like is underway.

A flat panel display module is generally composed of a flat panel in which cells are arranged in a matrix form between two glass substrates, a PCB module for driving the flat panel, and a case for protecting and integrating these. It consists of.

On the other hand, as shown in the overall circuit configuration diagram of a normal flat panel display module shown in FIG.
The PCB module that normally drives the flat panel 40 has the following configuration. R, G, B video data and synchronization signals are received from the outside
A (Flat Pin Grid Array) type custom IC (Integ
timing controller (Tc
on: Timing-controller) and the like to process and generate video data and various control signals so as to match the structure of the flat panel 40.
A low driver 20 for supplying a scanning signal to a low signal line by a low driver control signal 50 and a power supply 51 received from a power source 51, and a flat panel receiving video data processed by the main PCB 10 by receiving a data control signal 60 and a gradation voltage 61. It comprises a column driver 30 for supplying to 40.

[0005]

However, the main PCB
The conventional driving circuit embodied in FIG. 10 has a masking timing setting (MaskingTimin) in which the timing and various input driving interface conditions are limited to specifications set to match the panel.
g Setting) method, and it is impossible to make timing and drive changes and corrections according to changes in user conditions, display sources, and input conditions of monitor products. In other words, even if it is within the drivable range, unless the drive device performs hardware-based optional processing, it is impossible to optimize display characteristics in a fluid manner because the settings are fixed. This is because the input condition of the flat panel display basically has an input timing condition of VESA specifications, while the graphic source side has DDC (Digital) stored in the flat panel display module. Data Communicatio
n) Generate and display a digital interface timing control signal for driving the panel based on the information. In addition, the flat panel display monitor products released on the market have a gamma voltage and various power supplies for gray scale division.

According to the prior art, the addition of an option board allows the user to use an OSD (On Screen Displa).
y) Gamma, flicker voltage, brightness, scaling, FRC (Frame Rate Control)
l), I / O format, etc. can be adjusted. However, according to only such a function, the I / O (Input / Output) on the flat panel drive circuit should be used.
Optimal conditions can be achieved by changing the timing (changing the drive frequency or changing to the least optimal blanking time) to drive the optimal screen, or by processing the standard signal through additional circuitry in the graphics source As described above, even if the driving frequency is changed or a change to the minimum optimal blanking time is performed to provide a very good driving environment, the I / O format must satisfy a general-purpose display standard. Therefore, no matter how good the above conditions are, the risk of change must be very large.

In particular, an interface is required to drive a display source having a different I / O format for a monitor, and an additional system board capable of FRC adjustment if a difference occurs in the frame frequency or the number of blanking sections. (A / D board or D /
(D board etc.). Again, the flat panel display
Due to the limitation of the I / O format, the efficiency of the display product cannot be used 100%, the jitter due to the option board and the interface conditions between the two do not match well, which adversely affects the image quality of the monitor product. It cannot sufficiently contribute to characteristic optimization.

[0008] As described above, the fixedness of the flat panel display is generated because the display method is different from that of the CRT (Cathode Ray Tube) display. In the case of the CRT, the frame frequency is 40 Hz to 8 Hz.
Although it can be driven very widely up to 5 Hz, the driving method of the flat panel display is fixed by the characteristics of the panel. That is, if the frame frequency is the current panel characteristic optimized at 60 Hz, the driving condition is naturally optimized at the 60 Hz condition. If the graphics card or display source is all VES
Since the data does not conform to the A standard, a slight deviation occurs depending on the manufacturer, and data slightly different from the standard timing is supplied. Therefore, the optimum driving condition timing of the flat panel may be different from the VESA standard signal. In addition, when the standard signal is slightly deviated by a vendor, an additional option board is used to adjust the fluid timing as described above, but the function alone is not sufficient as mentioned above. It can be said that the cost is very large.

The reference of the Vesa display input timing is a blanking time (horizontal synchronization signal, horizontal synchronization signal,
Back porch, front porch (front)
porch)) and the blanking time (vertical synchronization signal, back porch, front porch) required to return to the first position at the last position where one frame has been scanned are specified for each frame frequency. However, since a flat panel drive uses a method such as an active matrix method instead of a scanning method, the time required for retrace after transmission of the last display signal of a line or a frame is very different from that of a CRT, and is extremely small. It is only necessary to have a blanking time of the order of the horizontal flyback or the line (vertical flyback). Also, by using an optional board such as an A / D board, the operating frequency increases due to unnecessary blanking time under VESA conditions, and the blanking time becomes long and unstable.
When O becomes unstable, the driving conditions of the flat panel become very unstable. Therefore, it is necessary to reduce the blanking time so that the flat panel can be driven under the optimum driving timing conditions, and to stabilize the display characteristics and improve the reliability.

Further, there are cases where the display characteristics must be adjusted differently depending on the deviation of the product or the environment and conditions of the user. In the case of such a flat panel monitor product, conventionally, it has been necessary to adjust by an additional option board or interface board having an optimum driving condition fixed to match the characteristics of the flat panel. However, when changing the optimal driving conditions fixed to the characteristics of the flat panel by adjusting the gamma, contrast, brightness, flicker, and other display characteristics, using an A / D board or an option board, The upper and lower tones contrasted by the clapping are interrupted, and the flat panel characteristic is reduced by 10%.
There was a problem that it could not be used at 0% efficiency.

Therefore, it is natural to eliminate the increase in cost and the like due to the use of the option board as described above, and a fundamental drive method for suppressing the occurrence of jitter and the like due to mismatch of interface conditions. Was needed. In other words, not only the resolution information and the information on the operating frequency such as the vertical frequency and horizontal frequency of the video signal, the main frequency of the video signal, but also the digital information on the gamma, flicker voltage, luminance value, etc., which can be adjusted by the user. A need has arisen to allow sharing between the graphic source and the flat panel display module and to allow the user to update it to allow for flexible changes in FRC, I / O format, other display characteristics information, and the like. In particular, even if the signal output from the graphic source is a video signal whose blanking time has been changed according to the user's definition in addition to the standard signal and which has been changed to the frequency of the video signal, basically the flat panel There is a need to be able to make the best use of it to drive the display.

Accordingly, it is an object of the present invention to use a serial bus with VESA standard DDC function to save and share I / O timing and other display characteristics within a drive without additional option boards. It is an object of the present invention to provide a flat panel display device which can be adjusted and uploaded, has a wide and flexible interface, and a driving method thereof.

[0013]

According to an aspect of the present invention, there is provided a flat panel display device for directly receiving digital video information and control signals from a graphic source via a serial bus. ,
A screen is displayed by generating digital video information and control signals suitable for panel characteristics.

According to another aspect of the present invention, there is provided a flat panel display device including a memory unit for storing digital display information directly input from a graphic source through a serial bus, and a digital display information received from the graphic source. A timing controller that extracts display information suitable for the corresponding flat panel from the memory unit and outputs a driving signal, and a data driver that outputs a video signal to a data line based on a number of signals received from the timing controller. And a scan driver for outputting a control signal to a gate line based on the plurality of signals received from the timing controller.

Here, the digital display information may include various types of signals suitable for a large number of flat panels.

The digital display information can be changed by a predetermined signal output from the graphic source to the serial bus by a predetermined data input by a user using a predetermined program.

The digital display information can be changed by a user inputting predetermined data using predetermined keys provided outside the flat panel display device.

Thus, in a flat panel display device which receives, processes and displays a display signal output from a graphic source unit via a serial bus, the graphic source unit transmits the display characteristic information of the flat panel from the flat panel display module via the serial bus. Is read and interpreted, a corresponding new standard display signal can be output. Here, the display characteristic information of the flat panel can be changed not only by a predetermined signal output from the graphic source unit to the serial bus in response to the user inputting predetermined data by a predetermined program, but also It can also be changed by the user inputting predetermined data using a predetermined key installed outside the flat panel display device, according to the deviation of the product or the environment and conditions of the user. The flat panel can be driven.

Also, a method of driving a flat panel display device according to the present invention includes the steps of storing digital display information directly input from a graphic source through a serial bus, and based on the digital display information received from the graphic source. Extracting display information suitable for a flat panel and outputting a driving signal; outputting a video signal to a data line based on the driving signal; and outputting a control signal to a gate line based on the driving signal. Performing the steps.

[0020]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a flat panel display according to a preferred embodiment of the present invention, in which a person having ordinary skill in the art can easily implement the present invention. This will be described in detail with reference to FIG.

As shown in FIG. 2, the basic configuration of the liquid crystal display (flat panel display) according to the embodiment of the present invention is a graphic source 3 including a graphic source section 310.
And a liquid crystal panel display module 400 including a connector 410, a D / A converter 420, a memory 430, and a timing controller 440. Here, in the liquid crystal display device according to the embodiment of the present invention, all the functions of the conventional option board can be realized, and even if the option board is removed, the further functions are maintained.
As a result, it also contributes to cost reduction. In addition, it is not necessary to use an option board as in the conventional configuration. However, even if this is adopted, there is no problem in realizing all functions according to the features of the present invention.

The graphic source unit 310 corresponds to a system for outputting a video signal, such as a PC body, that is, a device that generates and outputs a synchronization signal, a graphic signal, and other control signals as a part of the graphic source 300. In particular, by reading and interpreting display characteristic information of a liquid crystal panel (flat panel) used for a liquid crystal panel display module via a serial bus, a display signal of a new standard supported is output.

The connector 410 is a DVI or DS for receiving a display signal output from the graphic source unit 310 of the graphic source 300 such as a PC body and transmitted through predetermined cables 311, 312.
Refers to a serial bus connector such as UB.

The D / A conversion section 420 converts predetermined screen display information contained in the display characteristic information of the liquid crystal panel stored in the memory section 430 into an analog signal. That is,
Screen display information such as gamma, flicker voltage, and brightness, which must be supplied as an analog voltage after D / A conversion, among the display characteristic information of the liquid crystal panel that can be adjusted by the user, is converted into digital data values. And converts it to an analog voltage and supplies it to each corresponding circuit of the PCB module. Here, the above-described series of operations is executed under the control of the timing control unit 440, similarly to the operation of a general liquid crystal display device.

The memory section 430 stores display characteristic information of the flat panel which can be changed by the user, and is shared with the graphic source section 310. Here, the display characteristic information of the liquid crystal panel is information relating to the standard of the liquid crystal panel, such as resolution information for driving the liquid crystal panel and operating frequency information such as a vertical frequency and a horizontal frequency of a video signal and a main frequency of the video signal. And digital information about gamma, flicker voltage, luminance value, etc., which can be adjusted by the user. The memory unit that stores the above information is a user-writable PROM or a rewritable EP.
A non-volatile memory such as a ROM may be used.

The timing control section 440 receives a display signal output from the graphic source section 310 through a serial bus, performs an arithmetic operation on the display signal, and outputs a display signal for driving a liquid crystal panel. That is, a display signal of the liquid crystal panel such as a video signal and a control signal corresponding to the display characteristic information of the liquid crystal panel is output and supplied to each corresponding circuit of the PCB module.

The operation of the liquid crystal display according to an embodiment of the present invention having such a structure will be described in more detail.

First, in the case of a CRT, the frame frequency can be driven very widely from 40 Hz to 85 Hz.
In contrast to this, the driving method of the liquid crystal panel display is fixed by the characteristics of the panel. Therefore, if the frame frequency is optimized at the current panel characteristics of 60 Hz, the frame frequency is naturally set to 60 Hz. Driving conditions such as the timing control unit 440 are also optimized. However, the display of a general monitor up to now is such that a signal output from a graphic source 300 is fixed to a standard signal such as VESA by a liquid crystal panel display module 400, and an arithmetic processing of an option board and a timing controller is performed. It is possible to adjust and output the FRC and I / O format to some extent by the graphic source 300.
There is no case where the signal itself output from is adjusted for FRC or I / O format. In particular, the longer blanking time is necessary only for the CRT scanning method, and is not necessary for a display such as an active matrix method using digital signal processing such as a liquid crystal panel display. This is advantageous in driving a liquid crystal panel.

Accordingly, in the liquid crystal display device according to the embodiment of the present invention, the FRC or I / O of the signal itself output from the graphic source 300 without using an option board.
Not only can you adjust the / O format, you can also adjust the blanking time. The operation process is as follows.

The operation of the liquid crystal display according to the embodiment of the present invention as shown in FIG. 2 is as follows. First, a predetermined cable 3 is connected to a graphic source 300 such as a PC main body through a DVI or D-SUB connector 410.
When a predetermined power source installed for the entire operation is applied to the liquid crystal panel display module (or monitor) 400 connected to the liquid crystal panels 11 and 312, the display characteristics of the liquid crystal panel stored in the memory unit 430 are obtained. The information is transmitted to the graphic source unit 310 through the serial buses 411 and 412 as DDC information. The graphic source unit 310 interprets such information, and transmits various display signals corresponding to the interpretation result to the liquid crystal panel display module 400 through predetermined cables 311, 312.

At this time, unlike the related art, the shared DDC information between the graphic source unit 310 and the memory unit 430 of the liquid crystal panel display module 400 includes the display characteristic information of the liquid crystal panel.
At this time, the display characteristic information of the liquid crystal panel can be changed by a user using a predetermined application program or the like, and the changed information is updated in the memory unit 430 again. Is used again, the graphic source unit 310 reads and interprets the information according to the information updated in the memory unit 430. In other words, the user can directly adjust the input timing in the graphic source unit (PC, other display system) 310 by re-inputting the optimal conditions suitable for the liquid crystal panel to the graphic source 300 (recommand). Has become.

Here, the display characteristic information of the liquid crystal panel which can be changed by the user by a predetermined application program or the like includes, in addition to the FRC and I / O formats, the screen display (brightness, gamma, Information such as flicker). In particular, the blanking time existing in the standard video signal can be adjusted, and the liquid crystal display module 400 operates by receiving a signal of a new standard different from the VESA standard signal.

That is, as shown in FIG. 3, the conventional display signal generated by the graphic source section 310 is a synchronous signal section (a), a back porch (b), a section (c) on which video data is loaded, and a front section. The back porch (b) is slightly longer than the front porch (d). On the other hand, if the blanking time is adjusted according to the embodiment of the present invention, as shown in FIG. 4, the portion (g) on which the video data is loaded becomes relatively long, and the other synchronization signal portions (e), Back porch (f),
In addition, the front porch (h) and the like have only an appropriate portion necessary for signal processing for driving the liquid crystal panel, and are as narrow as possible. In the above description, the user adjusts the blanking time by using a predetermined application program or the like, because the standard information of the display signal, that is, the portion (g) on which the video data is loaded, the synchronization signal portion (e),
The time for the back porch (f) and the front porch (h) is defined, and the graphic source unit 310 generates a display signal of a new standard.

As described above, when new display characteristic information is updated in the memory unit 430, the graphic source unit 3
10 reads and interprets this information to generate a display signal corresponding to the information and transmits it to the liquid crystal panel display module 400. At this time, the transmitted display signal is transmitted to the D / A converter 420 and the timing controller 44 via the serial buses 411 and 412.
Also shared with 0. The timing control unit 440 generates a video signal and various control signals necessary for driving the liquid crystal panel, and supplies them to the corresponding circuits of the PCB module along the wiring 441. D / A converter 420
Also, under the control of the timing control unit 440 according to the display characteristic information stored in the memory unit 430,
The digital data corresponding to the states such as gamma, flicker, and luminance are D / A converted and supplied to each corresponding circuit of the PCB module along the wiring 421.

As described above, if the user adjusts the screen display (brightness, gamma, flicker, etc.) data indicating the display state of the screen by a predetermined application program or the like, an additional A / D board or the like is required. Since the existing OSD function can be realized by digital processing without using an optional board, the gamma value unique to the liquid crystal panel can be used in the entire area. That is, as shown in FIG. 5, when an optional board such as a conventional A / D board is used, due to the characteristics of the circuit, when adjusting the brightness (A), the brightness is higher than the reference gamma change (R). When adjusting the contrast when the tone value near the tone is lost (B)
However, as shown in FIG. 6, if the digital processing is performed according to the embodiment of the present invention, the brightness is adjusted (C) or the contrast is adjusted (D) as shown in FIG. Even so, since the gamma change near the reference gamma change (R) is almost maintained, the display capability of the liquid crystal panel can be maximized.

On the other hand, the user can adjust the display characteristic information of the liquid crystal panel indicating the display state of the screen through a predetermined application program or the like.
Also, this can be realized in combination with installing a predetermined key outside the liquid crystal display device and inputting predetermined data to a user so as to support the OSD function on all monitors. it can.

As described above, according to the embodiment of the present invention,
In a liquid crystal display device that receives, processes, and displays a display signal output from a graphic source unit 310 through a serial bus, the graphic source unit 310
Can read and interpret the display characteristic information of the liquid crystal panel by the liquid crystal panel display module 400 through the serial bus, and can output a display signal of a new standard corresponding thereto. Here, the display characteristic information of the liquid crystal panel is obtained by a user inputting predetermined data using a predetermined program, and outputting a predetermined signal corresponding to the data to be output to the serial bus by the graphic source unit 310. Not only can it be changed,
It can also be changed by the user inputting predetermined data using predetermined keys installed outside the liquid crystal panel display device.

The above description of the liquid crystal display device according to the embodiment of the present invention is not limited to the liquid crystal display device, but may be applied to a plasma display device (PDP) or an organic display device having a similar driving method on a PCB module. It can be applied to general flat panel display devices such as EL display devices,
Various changes and implementations of the present invention are possible without departing from the scope of the claims.

[0039]

As described above, in driving a flat panel display device according to the present invention, it is natural to eliminate an increase in cost and the like due to the use of an option board. Can be suppressed at the source.

Further, the display graphic card or display source reads the I / O format information through the serial bus or I ² C bus of an interface cable connector such as DVI or D-SUB, and reads the driving conditions of the flat panel to obtain I / O format information. Search for the optimal conditions for the I / O interface, specify the I / O timing required by the user or the display source, send the setting values to the flat panel again under the optimal conditions, and display the display required by the display source. By being able to set by timing, it is possible to support graphic signals under timing conditions of any standard other than VESA. In particular, when the display resolution is the same and the frame frequency is the same, driving can be performed even when the driving frequency of the flat panel is lower than the VESA standard. If the frequency is lowered, the charging time for pixel display is reduced due to the characteristics of the flat panel. And the display characteristics are improved because there is a margin for time in pixel data processing.

When the optimum driving condition timing of the flat panel is different from the VESA standard signal, or when the standard signal slightly varies depending on the manufacturer, such a fluid timing is determined by the serial bus (I ² C) of the timing controller. Input timing and output timing can be freely adjusted by an interface such as a bus, an SPI bus, and a 3-WIRE bus. Then, the data setting value is stored in a memory for storing DDC (Digital Data Communication) display information to share timing information, and accurate I / O information is stored and continuously updated. By making it possible to continuously adjust to changes in the external environment, D by changing driving conditions can be achieved without an additional optional system (such as an A / D board having a Scaler, DSP, or FRC function).
The control of the DC display information becomes possible, and the characteristics with respect to the timing margin of the monitor product can be secured in a wide range.

Among the display characteristics, gamma generates a fixed voltage externally by a resistance or voltage division method, and gamma is fixed to a target value. For this reason, if the contrast and brightness are adjusted by using an A / D board or other intermediate interface, gamma adjustment for the entire gradation cannot be performed, but the voltage can be freely set by the serial bus and the monitor product The gradation characteristic level is adjusted to a desired value without any change, so that the adjustment can be performed while using the luminance efficiency of the flat panel at 100%.

Also, the values adjusted by the user and the values set according to the requirements of the graphic source can be stored in a storage device such as a memory shared through a serial bus to share the information with the state of the monitor product and can be adjusted. Not only that, it is possible to update / re-input and manage the optimum display characteristic information.

[Brief description of the drawings]

FIG. 1 is a block diagram for explaining the entire configuration of a normal flat panel display module.

FIG. 2 is a block diagram showing a graphic source unit and a flat panel display module according to an embodiment of the present invention.

FIG. 3 is an example of a display signal generated in a graphic source unit according to the related art.

FIG. 4 is an example of a display signal generated in a graphic source unit according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating a gamma change when an option board is used according to the related art.

FIG. 6 is a diagram illustrating a gamma change when adjusting display characteristics through a serial bus according to an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Main PCB 20 Low driver 30 Column driver 40 Flat panel 50 Low driver control signal 51 Power supply 61 Gradation voltage 300 Graphic source 310 Graphic source part 311, 312 Cable 400 Liquid crystal panel display module 410 Connector for serial berth 411, 412 Serial berth 420 D / A conversion section 430 Memory section 440 Timing control section 441 Wiring

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09G 3/20 670 G09G 3/20 670Q // G02F 1/133 575 G02F 1/133 575 F-term (reference) 2H093 NA80 NC13 NC28 NC90 ND06 ND09 ND32 ND43 ND50 ND52 ND58 NE07 NE10 5C006 AA01 AF13 AF23 AF45 AF46 AF51 AF52 AF53 AF61 AF71 AF73 AF78 BB11 BF09 EC05 FA01 FA16 FA41 5C080 AA05 AA06 AA10 BB21 DD05 DD09 DD05 DD09

Claims (7)

[Claims] 1. A flat panel display device for receiving digital video information and a control signal directly from a graphic source via a serial bus, generating digital video information and a control signal suitable for panel characteristics, and displaying a screen. Display device. 2. A flat panel display device, comprising: a memory unit for storing digital display information directly input from a graphic source through a serial bus; and a digital display information suitable for the corresponding flat panel based on the digital display information received from the graphic source. A timing controller that extracts display information from the memory unit and outputs a drive signal; a data driver that outputs a video signal to a data line based on a number of signals received from the timing controller; and a number of signals that are received from the timing controller. And a scan driver that outputs a control signal to the gate line based on the signal of the flat panel display device. 3. The flat panel display according to claim 2, wherein said memory section is a nonvolatile memory. 4. The digital display information includes multiple forms of signals suitable for multiple flat panels.
The flat panel display device according to claim 2. 5. The digital display information can be changed by a predetermined data input by a user using a predetermined program and by a predetermined signal output from the graphic source to a serial bus.
4. The flat panel display device according to 1. 6. The digital display information according to claim 2, wherein the user can change the digital display information by inputting predetermined data using a predetermined key provided outside the flat panel display device. Flat panel display. 7. A method of driving a flat panel display device, the method comprising: storing digital display information directly input from a graphic source through a serial bus; and suitable for a flat panel based on the digital display information received from the graphic source. Extracting the display information and outputting a drive signal, outputting a video signal to a data line based on the drive signal, and outputting a control signal to a gate line based on the drive signal. And a driving method of a flat panel display device.