KR100299845B1 - How to set auto course for automatic fine adjustment of LCD monitor - Google Patents

Abstract

The automatic course setting method for automatic fine adjustment of the disclosed LCD monitor is performed by converting a sampling clock into a digital video signal when converting an analog signal into a digital signal when displaying a video signal input from a computer system such as a PC through an image display device such as an LCD monitor. This allows the course to be set automatically during fine adjustments that automatically adapt to the signal.

The automatic course setting method for automatic fine adjustment of the LCD monitor according to the present invention, when the video signal is input from the computer system, determines the operation mode of the input video signal, sets the standard course value, performs fine adjustment, and fine adjustment is completed. After the fine adjustment is completed, set the course for the current fine adjustment to the course of the currently input video signal.If the fine adjustment is not completed, change the course and repeat the process until the fine adjustment is completed. Allow courses to be set up.

Therefore, in the present invention, since the course is automatically set in the course of performing the fine adjustment, the general user does not adjust the course directly, thereby providing convenience to the user.

Description

How to set auto course for automatic fine adjustment of LCD monitor

The present invention relates to a method for setting an automatic coarse during automatic fine tuning of a liquid crystal display (hereinafter referred to as LCD) monitor, and more particularly, to input from a computer system such as a PC. When the video signal is displayed on the LCD monitor, the LCD monitor automatically adjusts the course during the fine adjustment to automatically adjust the sampling clock to the video signal during the conversion of the analog signal to the digital signal. It is about how to set up the course.

In general, an image display device such as an LCD monitor is lightweight, can be manufactured thinly, and has an advantage of displaying images cleanly without distortion, and its range of use, including notebook computers, is gradually expanding.

1 is a block diagram schematically showing the configuration of a conventional LCD monitor as described above.

As shown, the computer system 10 outputs a predetermined video signal to be displayed on the screen of the LCD monitor, i.e., color signals of R, G and B, and simultaneously the horizontal synchronizing signal H and the vertical synchronizing signal V. Outputs

The signal amplification controller 20 amplifies the level of the video signal output from the computer system 10.

The clamp 30 adjusts the brightness by varying the level of the video signal output from the signal amplification controller 20 according to the brightness control signal.

The analog / digital converter 40 converts the analog signal output from the clamp 30 into a digital signal and outputs the digital signal.

The microcomputer 50 controls the overall operation of the LCD monitor and detects and separates the horizontal synchronizing signal H and the vertical synchronizing signal V output from the computer system 10.

At this time, the horizontal synchronizing signal H and the vertical synchronizing signal V output from the computer system 10 to the microcomputer 50 are separately outputted, or the horizontal synchronizing signal H and the vertical synchronizing signal V are mixed. There are a variety of methods, such as outputting one synthesized synchronization signal, or mixing a horizontal synchronization signal H and a vertical synchronization signal V with a color signal of R, G, or B.

In addition, the microcomputer 50 determines the operation mode by the frequencies of the separated horizontal synchronization signal H and the vertical synchronization signal V, and recognizes the resolution according to the determined operation mode.

That is, the horizontal synchronizing signal H and the vertical synchronizing signal V output from the computer system 10 are CGA (Color Graphics Adapter) mode, VGA (Video Graphics Array) mode, SVGA (Super Video Graphics Array) mode, and XGA ( Since the frequency and resolution are different according to various operation modes such as an eXtended Graphics Array) mode, the microcomputer 50 determines this.

For example, in the CGA mode, the frequency of the horizontal synchronization signal H is 15.75 KHz, the frequency of the vertical synchronization signal V is 60 Hz, and the resolution is 640 × 350.

In the VGA mode, the horizontal synchronization signal H has a frequency of 31.5 KHz, the vertical synchronization signal V has a frequency of 60 Hz or 70 Hz, and the resolution is 720 × 350 or 640 × 480.

In the SVGA mode, the frequency of the horizontal synchronizing signal H is 35 to 37 KHz, the frequency of the vertical synchronizing signal V is interlace, and the resolution is 800x600.

In the XGA mode, the horizontal synchronization signal has a frequency of 48.36 KHz, the vertical synchronization signal has a frequency of 60 Hz, and the resolution is 1024 × 768.

When the microcomputer 50 recognizes the resolution according to the operation mode as described above, the separated horizontal synchronizing signal H and the vertical synchronizing signal V are output to the graphic controller 60.

The graphic controller 60 adjusts the frequency of the pulse signal output by varying the divided value of the phase locked loop (PLL) circuit 63 according to the resolution recognized by the microcomputer 50 described above to the LCD panel 70. Authorized to be displayed.

The graphic control unit 60 includes a quantization unit 61 for quantizing the video signal output from the analog-to-digital converter 40 and a resolution adjustment unit 62 for adjusting the resolution of the quantized data in the quantization unit 61. Consists of.

In the LCD monitor having such a configuration, conventionally, a sampling clock is converted into a video signal in a process of converting an analog video signal input from a computer system 10 such as a PC into a digital signal through an analog-to-digital converter 40. Fine tuning will be performed.

In addition, the course of adjusting the total number of dot clocks of one line of video signal applied from the computer system 10 to the number of standard dot clocks of each operation mode such as the above-described CGA, VGA, SVGA and XGA modes is adjusted.

In this case, when the total number of dot clocks of one line of video signal applied from the computer system 10 and the number of standard dot clocks according to each operation mode do not match, the user may fine tune and set a course using the OSD function keys. .

However, the coarse adjustment in the conventional LCD monitor as described above is a function that is not available in the commonly used cathode ray tube monitors, and a single line of video signal corresponding to each operation mode such as CGA, VGA, SVGA and XGA modes input from the video card. If the total dot clock of is different from the standard dot clock for each operation mode, it is very difficult and inconvenient for the non-expert user to adjust the course because the user must watch the screen and adjust the course using the OSD function keys. Of course, there is a problem that a careful learning process is required.

An object of the present invention is to finely adjust the sampling clock automatically to the video signal in the process of converting an analog signal into a digital signal when displaying a video signal input from a computer system such as a PC through an image display device such as an LCD monitor The present invention provides an automatic course setting method for automatic fine adjustment of an LCD monitor that enables automatic course setting.

1 is a block diagram schematically showing the configuration of an LCD monitor according to the prior art;

2 is a flowchart showing in detail the flow of automatic course setting during automatic fine adjustment of the LCD monitor according to the present invention.

The automatic course setting method for automatic fine adjustment of the LCD monitor according to the present invention for achieving the above object is to perform the fine adjustment by setting the standard course value by determining the operation mode of the input video signal when the video signal is input from the computer system. When the fine adjustment is completed, it determines whether the fine adjustment is completed, and sets the course for the current fine adjustment as the course of the currently input video signal.If the fine adjustment is not completed, the course is changed until the fine adjustment is completed. It is characterized in that the course can be set automatically by performing repeatedly.

Hereinafter, with reference to the accompanying drawings will be described in detail the automatic course setting method for automatic fine adjustment of the LCD monitor of the present invention.

FIG. 2 is a flow chart showing in detail the flow of automatic course setting during automatic fine adjustment of an LCD monitor according to the present invention. When a video signal is input from a computer system, a first step of determining an operation mode of the input video signal (S10, FIG. S20, a second step S30 of setting a standard course value, a third step S40 of performing fine adjustment after the standard course value is set, and determining whether the fine adjustment is completed as a result of the third step. The fourth step (S50) and the fourth step (S60) of setting the course of the current fine adjustment to the course of the input video signal when the fine adjustment is completed as the determination result of the fourth step (S50) If the result fine adjustment is not completed, the sixth step (S70) of changing the course and performing fine adjustment again, and if the fine adjustment is completed as a result of the sixth step, sets the course for fine adjustment as the course of the input video signal. If the fifth step is performed and fine adjustment is not completed, the seventh step S80 is performed by repeating the sixth step.

Next, the operation of the automatic course setting method in the automatic fine adjustment of the LCD monitor according to the present invention configured as described above will be described in detail.

First, in order to display the video signal output from the video card of the computer system through the LCD monitor, fine adjustment and course adjustment are required unlike general cathode ray tube monitors.

Because if the total number of dot clocks of one line of input video signal does not match the standard number of dot clocks for each operation mode provided by the LCD monitor, fine adjustment and course are not set correctly and the video signal will not be displayed properly. .

When the video signal outputted from the video card of the computer system is input to the LCD monitor (S10), the microcomputer of the LCD monitor inputs the CGA, VGA, SVGA, and CGA of the input video signal according to the frequency and resolution of the horizontal / vertical synchronization signal. Each operation mode such as the XGA mode is determined (S20).

Now, when the operation mode of the video signal is determined in the above-described step (S20), a standard course value is set (S30).

After the standard course value is set in step S30, fine adjustment is performed (S40).

After performing such fine adjustment, it is determined whether fine adjustment is completed (S50).

When the fine adjustment is completed as a result of the determination in step S50 described above, the course for the current fine adjustment is set as the course of the input video signal (S60).

However, if the fine adjustment is still not completed, fine tuning is performed again by changing the course value for the fine tuning currently being performed (S70).

As a result of fine tuning again, when the fine tuning is completed, the course for fine tuning at the completion point is set to the course according to the operation mode of the input video signal. Change is repeatedly performed until fine adjustment is made (S80).

Here, the automatic course setting method for the automatic fine adjustment of the LCD monitor of the present invention has been described using the LCD monitor as an example, but the present invention is not limited thereto. In addition, all the digital information is converted to analog according to a reference clock and then digitized again. Of course, it can be used in the device.

As described above, according to the automatic course setting method for automatic fine adjustment of the LCD monitor of the present invention, the course is performed in the process of performing fine adjustment when displaying the video signal corresponding to each operation mode input from the computer system through the LCD monitor. Because it is set automatically, the general user does not adjust the course directly, thereby providing convenience to the user.

Claims (1)

A first step of determining an operation mode of the input video signal when a video signal is input from the computer system; Setting a standard course value; A third step of performing fine adjustment when the standard course value is set; A fourth step of determining whether fine adjustment is completed as a result of performing the third step; A fifth step of setting a course for the current fine adjustment as a course of the input video signal when the fine adjustment is completed as the determination result of the fourth step; A sixth step of changing the course and performing fine adjustment again if the fine adjustment is not completed as a result of the fourth step; And When the fine adjustment is completed as a result of the sixth step, the fifth step of setting the course of the fine adjustment to the course of the input video signal is performed, and if the fine adjustment is not completed, the sixth step is repeatedly performed. Automatic course setting method for automatic fine adjustment of the LCD monitor, characterized in that the seventh step.