DE4336116A1 - Computer monitor display set=up method for colour, brightness and contrast - using microprocessor to control and store displayed image using commands of closed system, and to detect horizontal and vertical signals, display signals and monitor identification signals - Google Patents

Abstract

A microprocessor controls and stores the displayed image, and is connected to a vertical and horizontal synchronous signal control unit. Monitor identification signals (100-102) are used by the microprocessor to detect the synchronisation and display signals (R,F,B). The set-up signal is coded in the original display signal using the frequency polarity of HSYN and VSYN or equivalent signals. Geometric displays are provided for brightness, contrast, colour purity, VSIZE, VPHASE, HSIZE, HPHASE, PINCUSHION, etc.. USE/ADVANTAGE - With personal computer or workstation. Control signals can be received without monitor control panel.

Description

The present invention relates to an on-screen display Monitor setting procedure used.

A conventional monitor often has a multiple scan function for different display types. Every display type gives a display pattern again. Therefore, a variety of functions must be done beforehand can be set in order to obtain a suitable display image. Further the user must change the display pattern according to a display type according to his set preferred software. All of these requirements make for the setting of necessary constructions and procedures for the User and designer complicated.

Newer designs use a digital to analog converter to control the monitor's analog circuit. Such a converter can also receive the control command from the control panel of the user and set all setting parameters for each display type and the EEPROM of the monitor, as shown in FIG. 1.

The invention has for its object to a new construction create with which one can directly control commands from the connected system can receive without using the control panel on the monitor. According to the invention, this object is achieved by a monitor setting method solved according to claim 1.

The following serves to better explain the invention detailed description of an embodiment in connection with the drawing. Show it:

Fig. 1 is a block diagram of a conventionally designed digital control monitor;

Fig. 2 is a block diagram of the inventive design Digital control monitor;

Fig. 3 is a representation of an original display image;

Fig. 4 is an illustration of the monitor setting menu;

Fig. 5 illustrates the horizontal phasing;

Fig. 6 is a representation of the horizontal phase adjustment;

Figure 7 illustrates the fixed polarity of HSYN and VSYN; and

Fig. 8 is a representation of the coded polarity of HSYN and VSYN.

Reference is now made to FIG. 2. A microprocessor 1 is able to control and store a display image, such as the geometric display (VSIZE, VPHASE, HSIZE, HPHASE, PINCUSHION etc.), the brightness, the contrast, the color purity etc. The microprocessor 1 can also detect the signals from the connected system 2 , such as synchronous signals (HSYS, VSYN), display signals (R, G, B) and monitor identification signals (IDO-2) etc.

System 2 described above may be a personal computer or a work station. The system 2 can have a program stored in the memory. The program can be operated via a direct key on a keyboard 3 using an operating system (such as DOS) or can be executed using a command within the framework of the operating system. The program can run under a software system such as Windows, OS2, UNIX, or the image can be operated under any special operating system. The program can also be executed / operated via a display device (such as a mouse, for example) or other methods.

When the program is running, the setting menu of the monitor on the original display image is changed directly as shown in Figs. 3 and 4. Therefore, the original display image should be stored in memory or on the disk so that the original display image can be restored after the monitor is set.

In all setting processes, the functions are selected with the aid of the numerical keys or the mouse, after which the functions are set with the aid of the arrow keys, for example the function four HPHASE according to FIG. 4 is selected in order to determine the functions that have to be set . Fig. 5 shows that the display can be moved directly via the submenu to be set by the user.

When the submenu 5 is adjusted according to Fig., The user may press the arrow key or use the display device (mouse) in the direction of the displayed block. Then the display on the screen is immediately set to a number as shown in FIG. 6.

The following description shows how all of them Function selection and setting processes coded and fed to the monitor become:

HSYN and VSYN are widely used for screen synchronization via the monitor and are used to identify different types of monitors and display types. In a multi-scan monitor currently in use, an analog or digital circuit is used to distinguish the different types of displays. For this purpose, reference is made to FIG. 7. Each mode has a fixed HSYN and VSYN frequency and polarity, and the monitor has a predetermined circuit with respect to these signals.

Although according to the invention the microprocessor 1 is used in the monitor, the circuit of the monitor can be predetermined if the polarity is fixed. If system 2 is initiated by the user's request for a setting, then it can use the signals previously defined with an alternating polarity to deliver HSYN and VSYN for initiation and setting. The setting command from the user can be encoded on the signals of the alternating polarity and decoded by the microprocessor. In this regard, reference is made to FIG. 8. In order to eliminate the noise within the period of changing polarity, the signal at the midpoint between VSYN and HSYN must be interrogated, where (1,0) means VSYN-1 and HSYN-0. A guide code frequency such as (0.0), (0.1), (1.1), (1.0) corresponds to a required initiation setting process. The data is therefore encoded with two bits each time and each byte is encoded four times and decoded by the microprocessor 1 into one byte. The code "FF" (11111111) is reserved for the completion of the setting command.

From the foregoing it is clear that a PC system is in use an analog VGA interface (address input "3c2", bit 7 and bit 6) can control the polarity of HSYN and VSYN without additional circuitry.

Claims (6)

1. Monitor setting procedure that is used in an on-screen display finds a microprocessor to control and store the Display image using the setting command of a connected Systems is used, a system connected to the microprocessor is the setting command via the synchronous signals (HSYN, VSYN), Display signals (R, G, B) and monitor identification signals (IDO-ID2) deliver, and in which the microprocessor the above Can detect signals. 2. The method of claim 1, wherein the system by a Personal computer or a workstation is formed. 3. The method of claim 1, wherein the system Can encode setting signals in the original display signals. 4. The method of claim 1, wherein the monitor the coded setting signals that are to be set via the  Original display signals have been emitted by the connected system, can distinguish. 5. The method of claim 3, wherein the coding method Frequency polarity of HSYN and VSYN or any equivalent Signals used with which the setting signal on the monitor display can be reshaped. 6. The method according to claim 1, wherein the Setting command includes the display image, such as the geometric display (VSIZE, VPHASE, HSIZE, HPHASE, PINCUSHION etc.), Brightness, contrast, color purity, etc.