KR100447191B1 - Method for setting variable range of raster size in a monitor - Google Patents

Abstract

It is a method for setting the variable size range of the monitor that can compensate for the deviation of each set without additional protection circuit and limit circuit and operate on the linear drive curve to improve image quality and reduce cost. Extracting the characteristic value related to the horizontal screen size for each model, creating a screen size compensation function according to the characteristic value, and storing it in the microcomputer of the corresponding monitor; and monitoring the factory mode data set based on the monitor design specification by the production automation equipment. And setting the horizontal screen size maximum / minimum range according to the factory mode data and compensation function every time the monitor input signal is changed, so that the optimum design of image quality and performance is easy and the material cost can be reduced. Can reduce remediation costs and provide visual stability Can be.

Description

How to set variable size of monitor screen {METHOD FOR SETTING VARIABLE RANGE OF RASTER SIZE IN A MONITOR}

The present invention relates to a monitor and a horizontal screen size variable range setting method of the monitor.

In general, the monitor has a screen adjustment mode to adjust the horizontal screen size within a predetermined range. In other words, when the screen adjustment switch provided on one side of the monitor is pressed, the user selects the screen size adjustment menu among the screen adjustment menus displayed in the OSD form such as screen size, screen position, screen brightness, contrast, and the like. To make adjustments. The screen size is displayed differently according to the horizontal / vertical frequency supported by the video card of the main body.

As described above, the related art of setting the variable range of the horizontal screen size of the monitor is as follows.

First, in the absence of a circuit horizontal screen size limiting circuit and a protection circuit, a method of setting a variable range of a horizontal screen size is as shown in FIG. 1. Find a frequency that is variable in the range (S11). That is, it detects the change range of the horizontal screen size for each frequency and finds the frequency with the smallest change range and the frequency with the largest change range.

The output value when the horizontal screen size of the variable frequency in the maximum range is a predetermined minimum size is set as the minimum variable range of all frequencies (S12).

Subsequently, the output value when the horizontal screen size of the frequency that is variable in the minimum range is a preset maximum size is set to the maximum variable range of the entire frequency (S13).

Thereafter, all signals input to the monitor are varied only within the set minimum / maximum variable range.

As a result, the above-described method sets a minimum / maximum range in order to design the screen size to satisfy 70% to 120% of the monitor size, and this variable range is fixed to the average value measured at the development stage.

Meanwhile, when there is a circuit horizontal screen size limiting circuit and a protection circuit, a method of setting a variable range of the horizontal screen size finds a frequency that varies in a minimum range with respect to the horizontal screen size among the characteristics of the developed model as shown in FIG. 2. (S21). At this time, the minimum value is fixed regardless of the minimum range.

Subsequently, the maximum range is set by limiting the maximum circuit output by adjusting each set in the production process on the basis of the frequency varying in the minimum range (S22).

The signal input to the monitor is then varied within a preset minimum / maximum range regardless of the magnitude of the horizontal frequency.

In the method of setting the variable size range of the monitor according to the related art, in FIG. 1, since there is no method to compensate for the deviation of each set, the screen size is not overscanned or is over circuited due to excessive overscan. There is a problem in that the image quality is degraded by causing damage and eventually operating on a nonlinear drive curve.

In addition, in the case of the prior art Figure 2, the set deviation compensation is forced to be overscanned based on the frequency at which the operation screen size becomes the minimum in the production process for each set, so that a defective set that does not overscan does not occur, Since the cost increases due to the addition of the protection circuit and the production process, and the minimum value is fixed at the development stage, there is a possibility that the nonlinear drive curve is included and thus the reliability is lowered.

Therefore, the present invention has been made to solve the above-mentioned problems, the monitor that can compensate for the deviation of each set without a separate protection circuit and limit circuit and operate on a linear drive curve to improve the image quality while reducing costs Its purpose is to provide a variable size setting method of the screen size.

1 is a flowchart illustrating a method for setting a variable size range of a monitor according to the related art.

2 is a flowchart illustrating another example of a method for setting a variable size range of a monitor according to the related art.

3 is a flowchart showing a method for setting a variable size range of a monitor according to the present invention.

4 is a flowchart illustrating a method of extracting a characteristic value related to horizontal adjustment of FIG. 3.

FIG. 5 is a graph showing the change of the horizontal screen size according to the horizontal screen size register value of each horizontal frequency of FIG.

FIG. 6 is a graph showing the change of the horizontal screen size according to the horizontal frequency of each horizontal screen size register of FIG.

The present invention extracts the characteristic values related to the horizontal screen size for each model using the screen adjustment equipment, and creates a screen size compensation function according to the characteristic values and stores them in the microcomputer of the corresponding monitor, and monitor design specifications by the production automation equipment. And storing the factory mode data set as a reference in a memory of the monitor, and setting a horizontal screen size maximum / minimum range according to the factory mode data and the compensation function whenever the monitor input signal is changed.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the screen size variable range setting method of the monitor according to the present invention in detail.

3 is a flowchart illustrating a method for setting a variable screen size range of a monitor according to the present invention, FIG. 4 is a flowchart illustrating a method of extracting characteristic values related to horizontal size adjustment of FIG. 3, and FIG. 5 is a horizontal screen size for each horizontal frequency of FIG. 4. 6 is a graph illustrating a change in the horizontal screen size according to a register value, and FIG. 6 is a graph illustrating a change in the horizontal screen size according to the horizontal frequency of each horizontal screen size register of FIG. 4.

As shown in FIG. 3, the method for setting the variable size range of the monitor according to the present invention automatically extracts the horizontal screen size adjustment-related values for each frequency of the monitor input image in the product development stage by using the screen adjusting equipment (S31). ).

Then, the extracted horizontal size adjustment-related values are set in the production automation equipment (S32).

Subsequently, the production automation equipment corrects the horizontal screen size maximum / minimum value of the monitor factory mode using the horizontal size adjustment-related value, and stores the corrected factory mode in the EEPROM (S33) to set the variable horizontal screen size range. Is complete.

In this case, a method of automatically extracting the horizontal screen size adjustment-related value for each frequency of the monitor input image using the screen adjusting device will be described in detail with reference to FIGS. 4 to 6.

First, as shown in FIG. 4, the maximum / minimum variable specification of the horizontal screen size is determined based on the entire screen (S41). For example, if the total variable width of the horizontal screen size is 80 ± 5mm based on the entire screen of the monitor, the variable width is 40 ± 2.5mm based on one side of the vertical axis symmetry, and the bezel The bezel over value is 15 ± 2.5mm and the bezel under value is 25 ± 2.5mm.

Horizontal frequency [KHz] / Horizontal screen size [mm] Register Scaled 31.47 37.86 43.27 53.02 60.02 68.68 75.02 79.94 91.16 93.72 100 One 305 304 307 306 322 309 316 318 312 311 110 2 312 310 313 312 329 316 322 324 319 317 120 3 318 317 319 318 335 322 330 331 325 323 130 4 325 323 326 325 342 329 336 337 331 329 140 5 331 330 332 331 350 336 343 344 338 336 150 6 337 335 339 337 356 341 350 351 344 342 160 7 345 342 345 344 363 348 357 358 351 349 170 8 352 349 352 351 370 355 363 364 358 356 180 9 360 356 359 359 375 362 370 371 365 363 190 10 366 363 365 366 382 367 378 378 370 368 200 11 372 368 371 371 390 373 385 385 378 375 210 12 378 373 376 376 396 380 391 392 382 378 220 13 385 381 384 383 402 388 398 397 388 385 230 14 392 387 390 391 394 395 391 240 15 397 393 395 396 400 402 398

Subsequently, the characteristic curve of the horizontal screen size according to the deflection circuit and the deflection IC for each model is extracted (S42). First, as shown in Table 1, create a horizontal screen size data table for the change of the horizontal frequency register (Rsgister) and graph the horizontal screen size data for the change of the horizontal frequency register for the purpose of detecting the average size change width per step of scaling. In this case, as shown in FIG. 5.

In this case, Table 1 shows the results of experimenting with the horizontal screen size for the change of the register (Rsgister) for each horizontal frequency for an arbitrary sample set to show an example of data table preparation, and the graph of FIG. 5 is based on the VESA standard mode. The register value (X) is expressed as a scaled value (Y) to show the change per step. When the relationship between X and Y is expressed by a formula, Y = (X-100) / 10 + 1 Can be represented.

Accordingly, as shown in FIG. 5, since the change width of the horizontal size with respect to the variable width of the horizontal size register has a substantially constant value regardless of the horizontal frequency, the variable range may be constant for all modes.

Next, the change in the horizontal frequency vs. horizontal screen size for each horizontal screen size register is graphed as shown in FIG. 6 for the purpose of detecting the deflection offset variation value for each frequency.

Therefore, as shown in FIG. 6, the horizontal screen size change according to the register is not linearly proportional to the horizontal frequency, but when the frequency is subdivided, the offset deviation of each band satisfies 2 to 5 mm.

Based on the extracted characteristic curve and the detected factor, the required compensation characteristic (average size change width per step of size adjustment, deflection offset change value for each frequency) is detected (S43). In this case, when a signal corresponding to the factory adjustment mode is input, the above-described deflection offset can be excluded from consideration because the size data of the factory adjustment mode stored in the EEPROM is used as a reference, and when a signal not corresponding to the factory adjustment mode is input. Even in the factory adjustment mode, the variable width can be controlled within the 2 ~ 5mm error level based on the magnitude data of the nearest horizontal frequency signal.

Reference data necessary for programming is extracted from the detected compensation characteristic (S44).

In this case, when the total variable width of the register satisfying the horizontal screen size variable width (80 ± 5mm) is about 130 steps, the correlation between the registers satisfying the bezel over variable width (30 ± 3mm) with respect to the factory adjustment size is as follows. Same as

Max Bezel Over Size = Factory Adjusted Size Data + 60% of Total (78 Steps)

Minimum Bezel Under Size = Factory Adjustment Size Data-40% of the total (52 steps)

Since the factory adjustment size is adjusted within the error limit possessed by the automation equipment, most of one or more adjustments are made for each accurate and constant horizontal frequency section, so that the reliability to the reference value is high.

The horizontal screen size variable range setting method of the monitor according to the present invention has the following effects.

First, it is easy to select a section that maintains uniform drive performance, and accordingly, it is easy to optimize image quality and performance.

Second, it is possible to eliminate the horizontal screen size limiting circuit and the maximum swing limiting circuit for limiting the variable range of the register, thereby reducing the material cost.

Third, it is possible to delete the production process that is added for the management of each set of horizontal screen size maximum limit circuit can reduce the production time and cost.

Fourth, it is possible to reduce the readjustment cost due to the adjustment error and the storage error.

Fifth, since it provides a uniform horizontal screen size variable range can provide visual stability when the user adjusts the screen.

Claims (3)

In the horizontal screen size variable range setting method of the monitor, Extracting the feature values related to the horizontal screen size for each model using the screen adjustment equipment, and creating a screen size compensation function according to the feature values and storing them in the microcomputer of the corresponding monitor Storing, by the production automation equipment, factory mode data set based on the monitor design specification in the memory of the monitor; And setting a horizontal screen size maximum / minimum range according to the factory mode data and compensation function whenever a monitor input signal is changed. According to claim 1, And the horizontal screen size-related characteristic values include an average size change width per step of screen size adjustment and a deflection offset change value for each frequency. According to claim 1, The preparing of the compensation function according to the characteristic value may include creating a horizontal size data table according to a horizontal screen size register change for each horizontal frequency; Preparing a horizontal screen size curve according to a horizontal screen size register value for each horizontal frequency based on the table, and detecting an average size change per step of screen size adjustment according to the horizontal size; Preparing a horizontal screen size curve according to the horizontal frequency of each horizontal screen size register based on the table, and detecting a change in the deflection offset for each frequency accordingly; And adjusting a compensation function according to the average size change width per step of the screen size adjustment and the deflection offset change value for each frequency.