DE19724409C2 - Method and apparatus for modifying the orientation and position of a display on a monitor - Google Patents

Description

The invention relates to a method for modifying the Display orientation and the display position of a monitor for a computer system when the display mode of the Computer system changes, the computer system has built-in video output element and the monitor the video output element is connected via a bus. The The invention also relates to a device for modification the display orientation and the display position of one Monitor for a computer system when the display mode of the Computer system changes, the computer system has built-in video output element, and the monitor with the video output element is connected via a bus.

The present invention is based on a computer system out of an abnormal display orientation and display position on a monitor that can be prevented by a change of the display mode occur in the computer system, and the  automatically the display orientation and the display position according to the different display modes that can be set on can be displayed on the monitor.

Under the display orientation and the display position does one understand, among other things, the location of a screen Image in relation to the screen, that is the size of the Image in relation to the maximum size that can be displayed relative position of the image, a possible twist or Distortion of the picture and the like.

The Fig. 1 (prior art) shows a block diagram of a display architecture in a conventional personal computer (PC) system. In Fig. 1, the computer system can be divided into the computer 1 (the part to the left of the dashed line) and the monitor ( 60 ). The microprocessor 10 is the core of the computer 1 , which can process the control processes, mathematical operations and peripheral interruptions. The chipset 20 is used to form a bridge between the microprocessor 10 and the PCI bus (Peripheral Component Interconnection, PCI). In addition, the microprocessor 10 can access the main memory 30 via the chipset 20 . For INTEL PENTIUM PRO processors, chipset 20 can be implemented using the Intel 82441FX (PCI Bridge and Memory Controller (PMC)) and 82442FX (Data Bus Accelerator (DBX)) modules. Chipset 40 is used to control communication between the PCI bus and the ISA bus, for example with an Intel 82371SB (PCI / ISA IDE Accelerator (PIIX3)). The video display card 50 inserted into the ISA bus is used to manipulate display information and to feed video signals and associated synchronization signals to the monitor 60 via a bus or via a feed line 70 . Video display cards, or graphics cards, can share the signal processing tasks arising from the image processing with the microprocessor and thereby improve the resulting performance of the overall system. In addition to the video display cards, a dedicated chipset installed on a motherboard can be used to perform these functions. Furthermore, a video display card specially designed for a PCI bus can be used to achieve high speed data transmission.

Synchronization signals and video signals signal the display appearance and display details of the monitor 60 . Synchronization signals, including a horizontal synchronization signal and a vertical synchronization signal, are directly or indirectly applied to a deflection circuit of the monitor 60 and control an electron beam gun that scans the display screen of the monitor 60 . Video signals are used to control the brightness and color of the scanned display screen. There are two traditional ways to control the deflection circle of the monitor with respect to the horizontal / vertical synchronization signals. The first way is to reproduce vertical / horizontal blanking synchronizing signals from the original vertical / horizontal synchronizing signals, to adjust the vertical / horizontal synchronizing blanking signals according to the phase of the video picture, and this vertical / horizontal synchronization - Use blanking signals to control the deflection circuit. The second option is to use the original synchronization signals from the video card to directly drive the deflection circuit. The currents flowing through the horizontal / vertical deflection yoke are then changed in accordance with the current video image. Basically, both of these options can modify the display orientation and display position on the monitor.

The video signals transmitted from video display card 50 to monitor 60 include red, green, and blue color signals. The synchronization signals include the horizontal synchronization signal and the vertical synchronization signal. In a non-interlaced display mode, an image frame defined by the vertical sync signal is composed by a plurality of scanned lines defined by the horizontal sync signal. The Fig. 2 (prior art) shows signal diagrams of a video signal and an associated synchronizing signal. In Fig. 2, the video signal shown represents image data in a picture frame when the synchronization signal shown is the vertical synchronization signal. In addition, the video signal shown represents image data in one scan line when the synchronization signal shown is the horizontal synchronization signal. The relationship of the time lapse between the video signal shown in FIG. 2 and the synchronization signal is described below. The character A denotes the synchronization pulse duration, and the time period between two adjacent synchronization pulses is defined as the total time of one picture frame or one scan line. The characters B and F denote the back porch or black staircase time and the front porch or black staircase time. The front black staircase time F, the synchronization pulse duration A and the rear black staircase time B are referred to as an off or blanking time. This blanking or blanking time is used to define the retrace time when an electron gun has completed a scan line or frame and then starts again with a next scan line or frame. The color values of the video signal must be set to the darkest level during the flyback time to prevent the electron gun from illuminating the display screen during this period. The characters C and E denote a left / lower frame edge time or a right / upper frame edge time. The character D denotes the addressable time range and defines the time period during which image data are displayed on the monitor. The time ranges C, D and E are referred to as an active video time.

In practice, different video display cards can were made by different manufacturers, different video signals (red, green and blue) and Synchronization signals (horizontal and vertical) output. In order to bridge such differences, the Video Electronics Supplier Association (VESA) one sentence of standardized synchronization parameters for different display modes suggested. For example the proposed synchronization parameters for one Display mode with a vertical sampling frequency of 72 Hz and a display resolution of 640 × 480 Pixels listed below:

Horizontal scan

Total sampling time: 26.413 µs
Synchronization pulse duration: 1.270 µs
Front black staircase time: 0.508 µs
back black staircase time: 3.810 µs

Vertical scan

Total sampling time: 13.735 µs
Synchronization pulse duration: 0.079 µs
Front black staircase time: 0.026 µs
back black staircase time: 0.528 µs

These suggested display modes have different ones Timing specifications for different combinations of video display cards and monitors. If how theoretically conceivable, all video display cards made by manufactured by different manufacturers standardized specifications proposed by VESA for the output of the video signals and the Synchronization signals, the could Monitors from the start or in advance  save a variety of sets of display parameters, that correspond to these display modes and could be these modes activate if necessary and thus the display Optimize alignment and display position. Appropriate technologies, for example appropriate Display modes, parameter storage and parameter Retrieval are described in U.S. Patent No. 5,021,713 (Arai et al.) disclosed and should not be further discussed here to be discribed.

However, most of the video display cards are currently not fully compliant with the proposed standardized specifications, except for the Definition of the image resolution in the active video time. This is the result of various practical ones Considerations such as technical possibilities and Production costs. Because the timing characteristics of the Video signals and the synchronization signals by different video display cards are generated, are different is a step to manual Change the display orientation and position to be carried out when a display configuration changes to set the timing parameters.

Some commercial monitors have one automatic setting function to solve the problems caused by manually adjusting the monitor, such as the errors caused by manual Recruitment arise and the additional cost of a additional adjustment circuit. The automatic setting Function optimizes the monitor display by the following Steps. First, the active video time is shown by a Auto detection technology determined. The certain active Video time is used to move the front black stairs  Determine time and the back black staircase time. Then the timing relationship between the active Area and the front / rear cantilever times changed by calculating the front black stairs Time, the synchronization pulse duration and the rear Black stair time to the standardized To meet specifications.

However, such automatic setting Not in certain circumstances. The active video For example, the video signal time may not be enough Have image data by the one described above Auto detection technology can be recognized. For example is visible in a text mode in the DOS environment Area of the monitor essentially displaying a Prompt (prompt) or an input or output characters. It is obvious that part of the video’s active video time Video signal contains no image data and is not detected can be, or not as active video time can be detected. On the other hand is in one Graphic mode in the WINDOWS environment the entire active Video time of the video signal visible, that is with in other words, the total active video time is with image Data filled. For this reason, the auto Detection technology come to an abnormal image display if the computer system is operated in a DOS environment and the display mode or the operating system environment be changed (if, for example, the WINDOWS Environment is switched to the DOS environment).

FIG. 3A (prior art) shows a display screen of a computer system operating in a graphical environment (such as the Microsoft WINDOWS environment), and FIG. 3B (prior art) shows timing diagrams (timing) -diagrams) of the associated video signal and synchronization signal. In the illustrated case, the video signal has detectable image data during the active video time (including front and rear frame edge times and addressable times). Therefore, a monitor using the conventional auto-detection technique can accurately detect the front black staircase time and the rear black staircase time. On the other hand, Figure (3C) (prior art) shows a display screen of a computer system operating in a text-oriented environment, and Fig. 3D (prior art) shows timing diagrams of the associated video signal and synchronization signal. It can be seen that the image data which are transmitted with the video signal shown do not take up the entire defined active video time. Therefore, errors can occur if the corresponding timing characteristics are detected. Accordingly, the conventional auto detection technology cannot perform the task of automatically modifying the display orientation and position.

DE 37 22 169 C2 describes a method for adapting a multi-mode monitor to a personal computer, which has at least three steps:
Operating values, including those for the horizontal and vertical frequencies, are saved in the monitor for operating modes-specific addresses for frequently recurring operating modes. These operating values are generated with the help of test signals and stored in the monitor itself.

The personal computer connected to the monitor generated signals are saved with the Operating values compared in the monitor. This is in the monitor a comparison circuit, especially a separate one Microprocessor available.

If there is a match between those of the Personal computer delivered signals and in the monitor stored operating values, the operating mode associated with these operating values on Monitor set. The monitor is then in Controlled depending on the recognized operating mode.

The problem underlying the present invention is a Procedures for modifying the display orientation and the Display position, which the display Modify alignment and display position automatically and which prevents an abnormal display when the Display mode changes.

Another problem of the present invention is a  Procedures for modifying the display orientation and the Display position, which the setup  Procedure (setup) of the monitor driver simplified and a so-called "plug & play" functionality allows.

Another problem with the present invention is one To provide computer configuration that does the above mentioned methods for modifying the display orientation and can execute the display position.

The problem is solved by those in the independent Claims disclosed methods and devices solved. Special embodiments of the invention are in disclosed in the subclaims.

The present invention solves the above Problems from providing an initial procedure to modify the display orientation and the display Position on a monitor of a computer system when the Computer system display mode changes.

First, a variety of display parameter sets kept ready from the start or in advance. When the display mode of the computer system changes, one of the display parameter sets is selected which corresponds to the corresponds to the new display mode. Then the selected display parameter set via a bus that supports the Computer connects to the monitor to the monitor transfer. Synchronization signals through a video Source means of the computer system are generated also sent to the monitor. Finally, one Adjustment size according to the selected display Parameter set and the synchronization signals generated and used the display targeting and the display Modify position.  

The present invention further provides a second Procedures for modifying the display orientation and the Display position ready. First, a variety of Display parameter sets from the start or in the Prepared in advance in the monitor. If the computer system is switched on, these display parameter sets fetched and in a main memory of the computer saved. When the display mode of the computer system changes changes, one of the display parameter sets is selected, the corresponds to the new display mode. Then it creates Video output means modified synchronization signals, the the new display mode considering the selected one Display parameter set correspond. In conclusion, the Display orientation the display position according to the modified synchronization signals modified.

With regard to DE 37 22 169 C2, the Invention according to the independent claims Operating mode switchover on the part of the personal computer is carried out during the process according to DE 37 22 169 C2 be referred to as operating mode adaptation on the monitor side got to. The invention thus differs essentially from DE 37 22 169 C2 that the display Parameter set depending on the computer system is selected from the new display mode known there, while in DE 37 22 169 C2 on the part of the monitor Comparison of the received signals with stored ones  Operating values is carried out to the respective operating mode to recognize.

Various other aspects, advantages and characteristics of the present invention are from the detailed Description, the claims and the accompanying Drawings immediately visible.

The following detailed description is best found in To understand connection with the accompanying drawings; this description is only used to describe one For example, and in particular should not be interpreted as that the present inventive teaching to the following restrict described embodiments of the invention is.

Fig. 1 (prior art) is a block-diagram of a display architecture in a conventional personal computer (PC) system is.

Fig. 2 (prior art) shows a timing diagram of a video signal and a corresponding synchronization signal.

Figure 3A (prior art) illustrates a display screen of a computer system operating in a graphical environment.

FIG. 3B (prior art) shows the timing diagrams of a video signal and a synchronization signal belonging to FIG. 3A.

Fig. 3C (prior art) illustrates a display screen is a computer system that is operated in a text-based environment.

FIG. 3D (prior art) shows the timing diagrams of a video signal and a synchronization signal belonging to FIG. 3C.

Fig. 4 is a flow diagram showing a method for modifying the display orientation and the display position of a monitor in the first embodiment of the present invention.

Fig. 5 shows a configuration of a computer system for modifying the display orientation and the display position of a monitor in the first embodiment of the present invention.

Fig. 6A shows a signal distribution of the universal serial bus (Universal Serial Bus, USB).

Fig. 6B shows a signal distribution of the I ² C-Access- bus (I ² C bus access).

Fig. 7 shows timing diagrams of a video signal, a horizontal synchronizing signal and a horizontal blanking signal used in the calculation example.

Fig. 8 is a flow diagram showing a method for modifying the display orientation and the display position of a monitor in the second embodiment of the present invention.

Fig. 9 shows a configuration of a computer system for modifying the display orientation and the display position of a monitor in the second embodiment of the present invention.

As previously described, conventional monitors can due to the detection of an incorrect display mode display abnormal display. For this reason, the present invention another scheme for display- Modification to solve this problem. In one Computer system can be the computer running a processor the exact display mode at any time recognize the monitor during operation is to be applied. Therefore, using the display Information generated by the processor of the computer be acquired, the monitor in a correct display- Mode will be set, and the monitor will not be abnormal Display the ad. In the present invention, a Plenty of display parameter sets in advance provided. Each display parameter set that is for one of the predefined display modes is included  front black staircase times and the rear Horizontal Sync Black Stair Times Signal and the vertical synchronization signal. If necessary, each sentence can continue to Times and the synchronization pulse durations of the horizontal sync signal and vertical Synchronization signal included. Under use of these display parameters prepared in advance and the Transfer between the computer and the monitor, the Monitor according to a new display mode in one correct timing state.

Below are two advantageous embodiments of the present invention with reference to the accompanying Described drawings.

FIG. 4 shows a flowchart of a method for modifying the display orientation and the display position of a monitor in a first embodiment, and FIG. 5 shows a configuration of a computer system that carries out the method shown in FIG. 4 , The computer system shown in FIG. 5 includes a computer 1 and a monitor 60 , which is connected to the computer via a bus 70 . The computer 1 includes a microprocessor 10 , a video display card or graphics card 50 and a memory 52 for storing predefined display parameters which correspond to different display modes. The monitor 60 includes a controller 62 , a digital-to-analog (D / A) converter 64, and a monitor deflection control circuit 66 .

In the method shown in FIG. 4, a plurality of display parameter sets are first stored in the memory 52 of the computer 1 in advance (step S1). Each display parameter set is assigned to one of the display modes that are permitted for the monitor 60 . Each set contains the display parameters of the front black staircase times and the rear black staircase times of the horizontal synchronization signal and the vertical synchronization signal. If necessary, the total times and synchronization pulse durations of the horizontal synchronization signal and the vertical synchronization signal can also be included.

The microprocessor 10 of the computer 1 or the video display card 50 can detect whether or not the current display mode of the computer system needs to be changed during operation (step S2). Generally, when the display mode needs to be changed, the microprocessor 10 can send an interrupt instruction to receive a response from the video display card 50 . Thus, in such a mode switching operation, the microprocessor 10 and the video display card 50 can be informed of the change in the current display mode and the correct display mode to which they should switch. This detection procedure in step S2 can be carried out continuously during operation until a mode change situation occurs.

When a change in the display mode is detected in the computer system, a display parameter set corresponding to the new display mode after the change by the microprocessor 10 or the video display card 50 is read out from the memory 52 (step S3).

The read parameters are sent to monitor 60 via bus 70 , which connects computer 1 to monitor 60 (step S4). In addition, the synchronization signals generated by the video display card 50 can also be sent to the monitor 60 . Since the message transmitted from computer 1 to monitor 60 contains data format information, bus 70 must be a kind of interface bus capable of handling data format information. The Universal Serial Bus (USB) and the I ² C access bus (I ² C access bus) are two examples of this type of bus. However, it will be apparent to those skilled in the art that other interface buses capable of handling data format information can also be used in the present invention.

Finally, using the display parameters corresponding to the new display mode and the synchronization signals generated by the video display card 50 , the monitor 60 can generate modified synchronization signals and deflection currents that are used to measure the deflection yokes of the deflection - Control circuit, and thereby to modify the display orientation and the display position of the monitor 60 . In step S5, the controller 62 generates a setting increment, that is to say in particular also an increase or an increase in the setting size, for the display orientation and the display position in accordance with the selected display parameters and the synchronization signals. In step S6, the D / A converter 64 converts the setting increment into the modified synchronization signals according to the new display mode and the associated deflection currents. The modified timing signals and currents are then sent to monitor deflection circuit 66 to change the display orientation and position with respect to the new display mode. The monitor 60 can thus suitably display the monitor display.

The computer system includes at least three elements the purpose of serving the ad targeting and the Modify display position: A storage element to the display parameters that correspond to the different display modes correspond to being able to save in advance a data Readout element for retrieving a set of the display Parameters that correspond to a new display mode when the display mode is changed and a display Adjustment element for modifying the display orientation and the display position according to the recovered ones Display parameters.

The memory 52 shown in FIG. 5 serves as the storage element for storing the predefined display parameters. Since these display parameters must be present when the computer system is turned on, memory 52 may be implemented by Read Only Memories (ROM) or by Static Random Access Memories (SRAM). The memory 52 can be accommodated on the motherboard of the computer 1 , as shown in FIG. 5, or can be incorporated into the video display card 50 . Two advantages can be achieved by connecting memory 52 and video display card 50 . The first advantage is that the display parameters stored in the memory 52 can be arranged to correspond to the display modes supported by the video display card 50 . The second advantage is that the controller of the video display card 50 does not have to read the memory 52 via an external bus, which increases the processing speed.

The data readout element can be the microprocessor 10 or the controller of the video display card 50 . In the illustrated embodiment, the selected display parameters are transmitted to monitor 60 via bus 70 . The display setting circuit is implemented by the controller 62 , the D / A converter 64 and the monitor deflection circuit 66 .

In addition, the bus 70 between the computer 1 and the monitor 60 can be implemented using replacement pins of the conventional VGA (Video Graphics Array) interface.

The transmission protocol of the bus 70 can correspond to that of the universal serial bus (USB) and that of the I ² C access bus (I ² C access bus). FIGS. 6A and 6B respectively show the signal arrangements of the USB bus or the I ² C-bus access. In Fig. 6A, Vcc denotes a supply voltage and GND denotes the reference or ground potential. D + and D- identify a pair of differential data lines for data transmission. In Fig. 6B, lines SCL and SDA are used to transmit the clock signal and the data signals. The line SDA can transmit an information packet which contains addresses and data between a START bit and a STOP bit. For example, the display parameters, including the front black staircase times, the rear black staircase times, the synchronization pulse durations, and the total times of the horizontal / vertical synchronization signals, can be divided into two parts, one to represent an integer part of the data, and another to represent a decimal portion of the data. The divided integer parts and the decimal parts are then transmitted one after the other via the interface.

The following calculation example illustrates the practical procedure for setting the H phase and the H size. Fig. 7 shows the timing diagram of a horizontal synchronization signal, a video signal corresponding to the horizontal synchronization signal and a horizontal blanking (also black key or blank key) signal, which is divided by the monitor. In Fig. 7, the periods of the horizontal synchronization signal and the blanking signal are denoted by the symbol a. The symbols e and y each represent the pulse durations of the horizontal synchronization signal and the blanking signal. Further time parameters are defined with reference to FIG. 7. Regarding the H-phase setting, the setting goal is to move the display to the central area; in other words, the relationship f = g must be fulfilled. Therefore:

f = g = 0.5. (a - b - y) (1)

In addition, the following must apply to the timing relationship of the left part of FIG. 7:

x + e + c = y + f = y + 0.5. (a - b - y) (2)

According to equation (2):

x = 0.5. (a - b + y) - c - e (3)

The H-phase setting process can be carried out according to equation (3). In other words: The relationship f = g, which means that the display position is in the center of the display screen, is fulfilled if the following applies to the parameter x:

x = 0.5. (a - b + y) - c - e

It should be noted that the parameters a, y, b, c and e are known. Therefore, the monitor controller can be falling Flanks of the pulses of the horizontal synchronization Detect signal and the horizontal blanking signal and determine whether the distance between them is falling Edges is equal to the parameter x or not. If the Distance between the falling edges of the If the parameter x differs, the monitor controller can Set the horizontal blanking signal continuously until the distance is equal to the parameter x. Such a Adjustment process is also for modifying the vertical display position applicable.

Optimized parameters that are previously saved in the monitor must be used for the H-size setting. More specifically, the relationship between the part of (a - e) / b and a pulse width modulating parameter H _PWM , which is also referred to as the field value of the monitor, remains with respect to the horizontal size during the setting process constant. For example, the previously stored pulse width modulating parameter H _PWM with respect to the horizontal size is 50 and the optimized parameters a, b and e are:
a = 104 characters
b = 80 characters
e = 4 characters

It should be noted that the "character" is an illustration of the display parameter value, which indicates the practically displayed extent of a picture element according to the time values at a specific horizontal scanning frequency. In brief: If the ratio of (a - e) / b = 1.25 and H _PWM = 50 are fulfilled at the same time, then the horizontal size is optimized. Accordingly, the pulse width modulating parameter H _{PWM must} also be set if the ratio of (a - e) / b, which was calculated from the applied video signals and the synchronization signals, deviates from the optimized value of 1.25. For example, the practical parameters a, e, and b associated with the video signals and synchronization signals generated by the video display card are:
a = 128 characters
b = 100 characters
e = 9 characters
whereby the ratio of (a - e) / b = ( 128 - 9 ) / 100 = 1.19. According to the pulse-width-modulated _PWM parameter H to 50 × must (1, 19/1, 25) are set = 47.6. Such an adjustment process can also be used for modifying the vertical display size.

FIG. 8 shows a flowchart of a method for modifying the display orientation and the display position of a monitor in a second advantageous embodiment of the present invention, and FIG. 9 shows a configuration of a computer system which does the same in FIG. 8 performs the method shown. The computer system shown in FIG. 9 includes a computer 1 and a monitor 60 , which is connected to the computer via a bus 70 , similar to the configuration shown in FIG. 5. The computer 1 includes a microprocessor 10 and a video display card 50 . The monitor 60 includes a controller 62 and a memory 68 for storing predefined display parameters that correspond to different display modes.

In the method shown in FIG. 8, a plurality of display parameter sets corresponding to different display modes are first stored in the memory 68 (step S11). In this embodiment, memory 68 is installed in monitor 60 .

Each display parameter set contains the front ones Black stair times, the back black stair times, the total times and the synchronizing pulse durations of the horizontal sync signal and vertical Sync signal.

When switched on, the computer 1 reads out the stored display parameters and stores the read out parameters in the main memory 30 (step S12).

Such an arrangement can be the monitor setup process Simplify (monitor setup). The users have to do not install a monitor driver, which causes a "plug & play" functionality is achieved.

The microprocessor 10 of the computer 1 or the video display card 50 can detect whether or not the current display mode of the computer system needs to be changed during operation (step S13).

This detection procedure is carried out during operation  carried out continuously until a fashion change situation occurs.

When the computer system needs to be changed, the microprocessor 10 reads out a set of display parameters from the main memory 30 which corresponds to a new display mode and transfers the read values to the video display card 50 . The video display card 50 then generates modified synchronization signals belonging to the new display mode in accordance with the transmitted display parameters (step S4).

Finally, the monitor 60 recognizes the change in the display mode and switches to the corresponding new display mode (step S15). By using the D / A converter 64 and the monitor deflection circuit 66 , the monitor 60 can adjust the display orientation and the display position according to the new display mode.

In this embodiment, the computer system includes also at least three elements to achieve the purpose meet the display orientation and display position to modify: A storage element to display the Parameters that correspond to different display modes in the to be able to save in advance a data readout element for Retrieve the display parameter sets that are new Display mode correspond when the display mode changes and a display setting element for modifying the Display orientation and position according to the recovered display parameters.

The memory 68 shown in FIG. 9 serves as the storage element for storing the predefined display parameters. Since these display parameters must be present when the computer system is turned on, the memory 68 can be implemented by Read Only Memories (ROM) or by Non-Volatile Static Random Access Memories (SRAM). In this embodiment, memory 68 is installed in monitor 60 . The data readout element can be the microprocessor 10 or the controller of the video display card 50 . In this embodiment, all display parameters stored in the monitor 60 are transmitted to the computer 1 via the bus 70 when they are initially switched on. The function of the display setting element is then provided by the microprocessor 10 or the controller of the video display card 50 .

The foregoing description of preferred Embodiments of the present invention have been disclosed Given for the purpose of illustration and explanation. This description of the exemplary embodiments is not intended to be a be an exhaustive presentation of the inventive teaching, nor is the inventive teaching to the described Embodiments are considered limited. Many modifications and variations of those described Embodiments are without inventive for those skilled in the art To do something obvious or at least obvious. The exemplary embodiments described were selected and described the principles of solution of the invention and explain their practical application, and thereby others Specialists to enable the invention understand and various other embodiments and To create modifications for each specific requirements.

Claims (20)

1. A method of modifying the display orientation and display position of a monitor ( 60 ) for a computer system when the display mode of the computer system changes, the computer system having a built-in video output element ( 50 ) and the monitor ( 60 ) is connected to the video output element ( 50 ) via a bus ( 70 ),
and the method comprising the steps of:
Storing a plurality of display parameter sets in advance, each of the display parameter sets being generated in a display mode of the computer system,
Selecting one of the display parameter sets when the display mode of the computer system changes, the display parameter set being selected in accordance with a new display mode into which the video output element ( 50 ) has been instructed to switch,
Transmitting the selected display parameter set to the monitor ( 60 ) via the bus ( 70 ),
Delivering synchronization signals from the video output element ( 50 ) to the monitor ( 60 ),
Generating a setting increment for the display orientation and the display position by the monitor ( 60 ) in accordance with the selected display parameter set and the synchronization signals, and
Modify the display orientation and position according to the setting increment. The method of claim 1, wherein the step of modifying the display orientation and position is accomplished by generating modified synchronization signals and a deflection current in accordance with the setting increment and transmitting to a deflection circuit ( 66 ) the monitor ( 60 ). 3. The method of claim 1, wherein the new display mode after changing one Processor of the computer system is detected. 4. The method of claim 1, wherein each display parameter set the front Black staircase times (F) and the rear ones Black Stair Times (B) The Sync Signals included. 5. The method of claim 4, wherein each display parameter set continues to Pulse durations (A) and the total times of the Includes synchronization signals. The method of claim 1, wherein the video output element ( 50 ) is a video display card. 7. The method of claim 1, wherein the video output element is a display chip, which in the computer system is installed. 8. A method of modifying the display orientation and position of a monitor ( 60 ) for a computer system when the display mode of the computer system changes, the computer system having a built-in video output element ( 50 ) and the monitor ( 60 ) is connected to the video output element ( 50 ) via a bus ( 70 ), and the method comprises the steps:
Storing a plurality of display parameter sets in the monitor ( 60 ) in advance, each of the display parameter sets being generated in a display mode of the computer system,
Saving the display parameter sets to my memory element when the computer system is switched on
Selecting one of the display parameter sets when the display mode of the computer system changes, the display parameter set being selected in accordance with a new display mode into which the video output element ( 50 ) has been instructed to switch,
Generating modified synchronization signals in accordance with the new display mode by the video output element ( 50 ) in accordance with the selected display parameter set,
Modifying the display orientation and display position by the monitor ( 60 ) in accordance with the modified synchronization signals. 9. The method of claim 8, wherein the new display mode after changing one Processor of the computer system is detected. 10. The method of claim 8, wherein each display parameter set the front Black staircase times (F) and the rear ones Black Stair Times (B) The Sync Signals included. 11. The method of claim 8, wherein each display parameter set continues to Pulse durations (A) and the total times of the Includes synchronization signals. The method of claim 8, wherein the video output element ( 50 ) is a video display card. 13. The method of claim 8, wherein the video output element ( 50 ) is a display chip installed in the computer system. 14. A device for modifying the display orientation and the display position of a monitor ( 60 ) for a computer system when the display mode of the computer system changes, the computer system having a built-in video output element ( 50 ), and the monitor ( 60 ) is connected to the video output element ( 50 ) via a bus ( 70 ), comprising:
Storage means ( 30 , 68 ) for storing a plurality of display parameter sets which have been generated in a display mode of the computer system,
Data readout means for retrieving and reading out one of the display parameter sets corresponding to a new display mode, into which the video output element ( 50 ) is instructed to switch when the display mode of the computer system changes, and
Display setting means for generating a setting increment for the display orientation and the display position in accordance with the read out display parameter set of the readout means and synchronization signals from the video output means in order to change the display orientation and the display position of the monitor ( 60 ) to be modified. 15. The apparatus of claim 14, wherein the storage means installed in the computer system are. 16. The apparatus of claim 14, wherein the memory means are installed in the monitor.   17. The apparatus of claim 14, wherein the data readout means is a processor which in the Computer system is installed. The apparatus of claim 14, wherein the display setting means are installed in the monitor ( 60 ). 19. The apparatus of claim 14, wherein the video output means ( 50 ) is a video display card. The apparatus of claim 14, wherein the video output means ( 50 ) is a display chip installed in the computer system.