KR100459186B1 - Method and apparatus for automatic sensing input mode of a display device - Google Patents

Abstract

The present invention relates to an input mode recognition device and a method for automatically determining a mode by using average energy of WVGA and VGA, and WXGA and XGA. A mode determination unit for determining a signal, an A / D converter for converting an analog R, G, B video signal and a horizontal / vertical synchronization signal into a digital R, G, B video signal according to a mode determined by the mode determination unit; A memory for storing the digital R, G, and B video signals converted by an A / D converter, and an average energy calculator for calculating the average energy of the digital R, G, and B video signals stored in the memory and transferring the average energy to the mode determining unit. It calculates the average energy of XGA and WXGA and VGA and WVGA with the same frequency of horizontal / vertical sync signal, respectively, and processes the input video signal more accurately. Since there is an effect that can be obtained high quality images.

Description

Apparatus and method for recognizing input mode of image display device {Method and apparatus for automatic sensing input mode of a display device}

The present invention relates to an image display device, and more particularly, to an apparatus and method for recognizing an input mode of an image display device.

In general, a monitor is a device that displays a video signal of a predetermined format transmitted from an associated PC video card on a screen through a series of signal processing such as digital sampling and scaling.

Since such monitors have horizontal and vertical sync signal frequency limits of the input image that can be processed by their models, they are processed if the horizontal and vertical sync signal frequencies of the video input from the PC are within the limits. If it exceeds, image processing is not performed.

That is, general monitors do not have perfect compatibility with video signals having various resolutions and frequencies input from the PC, and users cannot manually display normal screens when inputting unsupported signals to the monitors. We also changed the settings.

In this way, the video signal output from the PC is defined by the VESA standard to define a signal of a certain format (position of video signal, polarity of horizontal / vertical sync signal, etc.) by horizontal resolution, vertical resolution, vertical frequency, and horizontal frequency. It is decided by.

The video signal of the PC is controlled by a control panel program called "screen display setting" of Windows. Here, the user can convert the setting of the horizontal / vertical resolution, the horizontal / vertical frequency conversion is common.

Hereinafter, an input signal processing method of a monitor according to the prior art will be described in detail with reference to the accompanying drawings.

1 is a flowchart illustrating an input signal processing method of a monitor according to the related art.

Referring to FIG. 1, first, an image signal is received from a PC (S1).

It is determined whether the input video signal is a signal supported by the corresponding monitor (S2).

Subsequently, if the input image signal is a signal supported by the corresponding monitor (S2), the input image signal is displayed on the screen (S3).

When the video signal is displayed on the screen, the monitor enters the control standby mode (S4).

On the other hand, if the determination result (S2), if the input video signal is not a signal that can be supported by the monitor blanking the screen and outputs an error message in the OSD form (S5).

As described above, the microcomputer of the monitor determines whether the PC signal inputted to the monitor is a resolution / frequency signal supported by the monitor.

If a signal supported by the monitor is input from the PC, the input video signal is processed into a displayable signal on the screen and displayed on the screen, and then waits for the next operation, and monitors whether the input signal changes.

On the other hand, when a signal not supported by the monitor is input from the PC, blanking is performed and an error message is displayed in the OSD form.

As described above, the monitor according to the prior art cannot automatically determine the WVGA and VGA signals and the WXGA and XGA signals having the same horizontal / vertical frequency when the mode of the PC signal is determined by the frequency of the horizontal / vertical synchronization signal. There was a problem that caused image quality deterioration through mode misrecognition.

An object of the present invention is to provide an input mode recognition apparatus and method for an image display device that can automatically determine a mode using average energy of WVGA and VGA, and WXGA and XGA. There is this.

1 is a flowchart illustrating a method of recognizing an input mode of an image display apparatus according to the related art.

2 is a block diagram showing an input mode recognition apparatus of an image display device according to the present invention.

3 is a flowchart illustrating a method of recognizing an input mode of an image display device according to the present invention.

4 is a graph showing the amount of brightness of the image over time according to the input mode

Explanation of symbols for main parts of the drawings

10: Mode judgment part 20: A / D converter

30: memory 40: average energy calculation unit

In order to achieve the above object, the apparatus for recognizing an input mode of an image display device includes a mode determination unit for determining a mode by receiving a horizontal / vertical synchronization signal of an image signal input from a PC, and the mode determination unit. A / D converter which converts analog R, G, B video signal and horizontal / vertical sync signal into digital R, G, B video signal according to the mode, and digital R, G, B video converted by the A / D converter. And a memory for storing a signal, and an average energy calculator for calculating average energy of digital R, G, and B image signals stored in the memory, and transmitting the average energy to the mode determining unit.

According to an aspect of the present invention, there is provided a method of recognizing an input mode of an image display device, the method comprising: determining an input mode by receiving a horizontal / vertical synchronization signal; calculating an average energy of the determined input mode; And determining a current mode according to the calculated average energy, and displaying a video signal according to the determined mode.

Hereinafter, an input mode recognition apparatus and method of an image display device according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating an input mode recognition apparatus of an image display apparatus according to the present invention, and FIG. 3 is a flowchart illustrating an input mode recognition method of the image display apparatus according to the present invention. b) is a graph showing the amount of brightness of the image over time according to the present invention.

As shown in FIG. 2, the apparatus for recognizing an input mode of an image display device according to the present invention receives a horizontal / vertical synchronization signal of an input image signal and determines whether an XGA mode signal or a VGA mode signal is input. A / D converter for converting the analog R, G, B image signal input according to the mode determined by the mode determination unit 10 and the digital R, G, B image signal for judging 20, a memory 30 for storing digital R, G, and B video signals converted by the A / D converter 20, and a digital R, G, B video signal stored in the memory 30. It consists of an average energy calculation unit 40 for calculating the average energy.

At this time, the mode determination unit 10 determines the mode according to the horizontal / vertical synchronization signal input from the first PC, and subsequently accurately determines the current mode according to the energy level calculated by the average energy calculator 40. Done.

Because the input mode is any one of XGA, WXGA, VGA, and XVGA. The XGA and WXGA signals, the VGA and WVGA signals have the same horizontal / vertical frequency, so only the horizontal / vertical sync signal is input. Because you can not judge.

That is, when the VGA or XVGA signal is input, the mode determining unit 10 determines only the same horizontal / vertical frequency to determine the VGA mode, and the digital signal is converted by the A / D converter 20 at the frequency of the VGA signal. Sample to convert to a signal.

The digital R, G, and B video signals converted by the A / D converter 20 are stored in the memory 30, and the average energy is calculated through the average energy calculator 40 from the stored images. Transfer to the determination unit 10.

In addition, the A / D converter 20 performs sampling once more in the WVGA mode and stores the data in the memory 30, and calculates average energy from the stored image through the average energy calculator 40. Transfer to the mode determination unit 10.

Therefore, the mode determination unit 10 may accurately determine the resolution mode of the currently input video signal by comparing the average energy value in the VGA mode and the average energy value in the WVGA mode.

Subsequently, the A / D converter 20 converts the digital image data to be finally displayed according to the mode determined by the mode determination unit 10.

Referring to FIG. 3, the method for determining the input mode of the monitor according to the present invention configured as described above is first calculated in step S11.

It is determined whether the calculated frequency is the VGA mode or the XGA mode (S12).

Subsequently, when the frequency is the XGA mode, the determination result (S12) performs A / D conversion in the WXGA mode to calculate the first average energy Pw1 of the first 64 pixel value of the effective image section (S13).

In addition, A / D conversion is performed in the XGA mode to calculate the second average energy Pn1 of the first 48 pixel values of the effective video section (S14).

In operation S15, it is determined whether the calculated first average energy Pw1 has a larger value than the second average energy Pn1.

Subsequently, when the determination result (S15), the first average energy (Pw1) has a value larger than the second average energy (Pn1), it is determined that the current image mode is the WXGA mode (S16).

On the other hand, when the determination result (S15), the first average energy (Pw1) has a value smaller than the second average energy (Pn1) it is determined that the current image mode is the XGA mode (S17).

On the other hand, if the frequency (S12), if the frequency is the VGA mode A / D conversion in the WVGA mode to calculate the third average energy (Pw2) of the first 64 pixel value of the effective image section (S 18).

In addition, A / D conversion is performed in the VGA mode to calculate a fourth average energy Pn2 of the first 48 pixel values of the effective video section (S19).

In operation S20, it is determined whether the third average energy Pw2 and the fourth average energy Pn2 have a larger value.

Subsequently, when the third average energy Pw2 has a larger value than the fourth average energy Pn2, it is determined that the current image mode is the WVGA mode (S21).

On the other hand, if the third average energy (Pw2) has a smaller value than the fourth average energy (Pn2) (S20), it is determined that the VGA mode (S22).

In addition, when the input mode is neither XGA nor VGA, it is determined as a calculated mode according to the horizontal / vertical frequency of the input video signal (S23).

Finally, an image signal input according to the image mode determined as the current mode is displayed (S24).

As described above, in the present invention, in order to recognize the XGA and WXGA mode, VGA and WVGA mode of the same horizontal and vertical synchronization frequency, respectively, the average energy calculation unit () calculates the average energy through the following equation, and Determine the correct mode accordingly.

Mean energy = Σ (sampled data) ^ 2 / number of data

That is, when comparing the VGA and XVGA signals having the same horizontal / vertical frequency horizontally with only one line, the number of effective pixels becomes 640: 853, which is 3: 4. Therefore, sampling at 853 and sampling at 640 are values for sampling four and three values in the same interval, respectively.

4 (a) shows an 853 × 480 mode in which the original image mode is WVGA, and a case where the sample is sampled in 853 × 480 mode and a sample in 640 × 480 mode. In other words, it is an analog signal that produces 853 × 480 images, and when ADC converts it into 853 samples in the effective screen section, the average energy of four values is calculated from the beginning, and 640 samples are collected from the beginning. The average energy for the dog values is calculated by Equation 1 above.

At this time, if the average energy in the case of sampling at 853 × 480 is calculated by applying the above equation (1),

Average energy = (3 ^ 2 + 9 ^ 2 + 3 ^ 2 + 6 ^ 2) / 4 = 33.75

In addition, if the average energy in the case of sampling at 640 × 480 is calculated by applying the above equation (1)

Average energy = (5 ^ 2 + 5 ^ 2 + 6 ^ 2) / 3 = 28.66

Therefore, as shown in Fig. 4A, the sample has been sampled at 853 x 480, which is the same as the digital data produced by the original graphics card, and thus the average energy is larger than that sampled at 640 x 480.

In addition, as illustrated in FIG. 4B, the original image is a 640 × 480 mode sampled in the VGA mode in the 640 × 480 mode and a 853 × 480 mode sampled in the WVGA mode.

First, an average energy of four values may be obtained from the beginning by sampling 853 pieces in the effective screen section, and an average energy of three values may be calculated from the beginning by sampling the 640 pieces by the following equation.

That is, if the average energy in the case of sampling at 853 × 480 is calculated by applying the above equation (1),

Average energy = (3 ^ 2 + 8 ^ 2 + 11 ^ 2 + 8 ^ 2) / 4 = 64.5

In addition, if the average energy in the case of sampling at 640 × 480 is calculated by applying the above formula (1),

Average energy = (4 ^ 2 + 12 ^ 2 + 8 ^ 2) / 3 = 74.66

Accordingly, by sampling at 640 × 480 having a larger value than sampling at 853 × 480, it is possible to determine whether the input mode is the VGA mode or the WVGA mode.

As described above, the present invention determines the mode according to the input horizontal / vertical synchronization signal and performs sampling accordingly. The average energy of XGA and WXGA having the same frequency of the horizontal / vertical synchronization signal and VGA and WVGA is determined. By calculating each, it is possible to accurately distinguish the input modes and display the video signal.

As described above, the apparatus and method for automatically determining the input mode of a monitor according to the present invention calculates the average energy of XGA and WXGA and VGA and WVGA having the same frequency of horizontal and vertical synchronization signals, respectively, so that the input image signal can be more accurately measured. Since it can be processed and displayed, there is an effect of obtaining a high quality image.

Claims (7)

A mode determination unit which receives a horizontal / vertical synchronization signal of an image signal input from a PC and determines a mode; An A / D converter for converting analog R, G and B video signals and horizontal / vertical synchronization signals into digital R, G and B video signals according to the mode determined by the mode determination unit; A memory for storing the digital R, G, and B video signals converted by the A / D converter; And, And an average energy calculator for calculating average energy of the digital R, G, and B image signals stored in the memory and transferring the average energy to the mode determiner. In the resolution determination method of the monitor, Determining an input mode by receiving a horizontal / vertical synchronization signal; Calculating an average energy of the determined input mode; Determining a current mode according to the calculated average energy; And, And displaying the video signal according to the determined mode. The method of claim 2, The determining of the input mode is a step of determining whether the frequency of the input horizontal / vertical synchronizing signal is VGA mode or XGA mode. The method of claim 2, Calculating the average energy Calculating the first average energy PW1 by sampling the input video signal with WXGA when the XGA mode is determined in the input mode determination step; And calculating the average energy PW1 by sampling the input image signal with the WXGA, and then calculating the second average energy Pn1 by sampling with the XGA. The method according to claim 2 or 4, The determining of the current mode Determining that the current mode is the WXGA mode when the first average energy Pw1 has a larger value than the second average energy Pn1; If the first average energy (Pw1) has a value less than the second average energy (Pn1), the current mode is determined by the XGA mode characterized in that the step of determining the resolution of the monitor. The method of claim 2, Calculating the average energy Calculating a third average energy PW2 by sampling an input video signal using WVGA when the VGA mode is determined in the input mode determination step; And calculating the average energy Pw2 by sampling the input image signal with the WVGA, and then calculating the fourth average energy Pn2 by sampling with the VGA. . The method according to claim 2 or 6, The determining of the current mode Determining that the current mode is the WVGA mode when the third average energy Pw2 has a larger value than the fourth average energy Pn2; And determining the current mode as the VGA mode when the third average energy Pw2 has a smaller value than the fourth average energy Pn2.