DE10108971A1 - Video picture processing system measures clock rate selects correct resolution - Google Patents

Abstract

The video picture processing system takes the video signal (54) vertical (56) and horizontal (58) synchronization signals and pixel clock (6) and selects from a table the correct values of vertical and horizontal resolution for use by the output unit (50).

Description

The invention relates to a method for processing Video image signals in an image display device according to the genus Concept of claim 1 and a corresponding picture Playback device according to the preamble of claim 4.

In such picture display devices, video picture signals are turned off a video image signal source, such as a computer, transformed into a sequence of video images on one image screen are displayed. Over time, a Transition from conventional cathode ray tube imaging devices to modern liquid crystal image display devices and projectors. Regardless of the type used, a must Image display device can be vertical and hori zonal resolution of the video image based on the video image signals to determine the video images on the image to be able to display the screen correctly. Can display the image If the resolution is not determined correctly, it can video image displayed on the screen may be blurred or have an incorrect size. In such cases the Users manually adjust the size or resolution of what can be extremely annoying.

A conventional image display device receives the video image signals from a computer via a cable with a more number of signal conductors. The video image signals contain one Plurality of video signals, vertical synchronization signals  (Vs) and horizontal synchronization signals (Hs). To Receiving the video image signals processes the image reproduction gets these signals and gives on his screen correspond video images again according to the frequency of the verti kalen and the horizontal synchronization signals. Meanwhile are the frequencies of the vertical and horizontal synchronizers sation signals alone are not sufficient to the resolution to determine all video images.

Proceeding from this, the object of the invention is to specify a way with which the resolution from the determine received video image signals accurately and reliably leaves.

This task is according to the invention with signal processing The method of claim 1 and the image display device Claim 4 solved. The subclaims also give going to advantageous design options.

As can be seen more clearly from the following detailed According to the invention, the description can be video images based on the frequencies of the vertical and the horizontal synchronization signal and a pixel clock signals played. The resolution can be adjusted accordingly always determine the video image signals correctly.

The invention will now be described by way of example with reference described in more detail on the accompanying drawings. From the sen shows

Fig. 1 is a diagram of a reproduced with a conventional image reproducing device video image,

Fig. 2 is a resolution table, such as is conventionally used for the determination of the resolution,

Fig. 3 is a block diagram of a video image signal receiving image display apparatus according to the invention,

FIG. 4 shows a functional block diagram of the image display device from FIG. 3, FIG.

Fig. 5 is a functional block diagram of a first Frequenzzähl circuit of Fig. 3,

Fig. 6, the resolution table appearing in Fig. 4 and

Fig. 7 is a flow chart of the image processing method according to the invention.

The video image 12 shown in FIG. 1 is such as is reproduced by a conventional image display device according to US Pat. No. 5,367,337. This image reproducing apparatus reproduces a plurality of video images 12 based on video image signals obtained from a computer, which are displayed frame by frame. Each video image 12 contains a plurality of scan lines 14 , each of which contains a plurality of pixels 16 (the squares appearing in FIG. 1). The video image 12 can have different resolutions. For example, a resolution of 800 × 600 means that the video image has 600 scan lines 14 , each with 800 pixels 16 .

The vertical synchronization signals serve to indicate the frequency with which the video images 12 change, while the horizontal synchronization signals serve to indicate the frequency with which a scan line 14 is passed to the next. That is, in response to a vertical synchronization signal, the image display device reproduces a new video image on the screen. In response to a horizontal synchronization signal, a new scanning line 14 appears in the next position below. For example, if a vertical resolution of 400 is required (with a scan range of approximately 45 scan lines) and the frequency of the vertical synchronization signal is 85 Hz, the frequency of the horizontal synchronization signal from the computer must be 37.9 kHz.

The conventional image display device using a resolution table according to FIG. 2 determines the resolution of the video images by comparing the frequency of the received synchronization signals with the resolution table 20 . The resolution table 20 contains combinations of the frequency of the vertical and horizontal synchronization signals and the resolutions associated with each of these combinations. When the video image signal is received, the image display device determines the frequency of the vertical and horizontal synchronization signals and then determines the required resolution using table 20 . If the frequency of the vertical and horizontal synchronization signals is, for example, 85 Hz or 37.9 kHz, then the resolution according to Table 20 is 640 × 400 the resolution 1,024 × 768 taken from Table 20 for this purpose.

However, the conventional image display device cannot determine all the correct resolutions for a PC monitor. If the desired resolution is, for example, 640 × 400 and the frequency of the vertical synchronization signal is 85 Hz, the frequency of the horizontal synchronization signal is, as stated, 37.9 kHz. However, if the desired resolution is 720 × 400, the frequencies of the vertical and horizontal synchronization signals are also 85 Hz and 37.9 kHz. For this reason, the image display device cannot use the resolution table 20 to recognize whether the desired resolution should be 720 × 400 or 640 × 400. In such cases, the image display device must "guess" the desired resolution, as a result of which the video image appearing on the screen can be unstable or can have incorrect dimensions.

Video image signals 52 are received by the image display device 50 according to the invention shown in FIG. 3. For this purpose, the image reproduction device 50 is in electrical connection with a video image signal source 40 via a cable (not shown). The video image signals 52 include a plurality of video signals 54 , vertical synchronization signals 56 , horizontal synchronization signals 58 and pixel clock signals 60 , which arrive at the image reproduction device 50 via different signal conductors. The pixel clock signals 60 serve to control the playback frequency of the pixels in the image display device 50 . A are received, genes pixel clock signal 60 toward the image reproducing apparatus 50 represents a new pixel in a scan line on the basis of the video signals 54th

According to FIG. 4, the image reproducing apparatus 50 includes an image screen 68 for displaying the video images 12, a first Frequenzzählschaltkreis 72 for receiving the pixel clock signals 60, a second Frequenzzählschaltkreis 76 for receiving the vertical synchronization signals 56 and horizontal Syn chronisationssignale 58 and a control circuit 70 for receiving of video image signals 52 . The screen 68 can consist of an LCD panel or a digital monitor with a cathode ray tube. The first frequency counter circuit 72 serves to determine a pixel clock frequency after the pixel clock signals 60 . The second frequency counter circuit 76 is used to determine a vertical frequency from the vertical synchronization signals 56 and a horizontal frequency from the horizontal synchronization signals 58 . The control circuit then determines an appropriate resolution for the screen.

As shown in FIG. 4, the control circuit 70 includes a memory 78 for storing a resolution table 80 . The resolution table 80 contains possible combinations of vertical synchronization signals 56 , horizontal synchronization signals 58 and pixel clock signals 60 as well as a specific resolution for each of the combinations. The control circuit 70 compares the vertical frequency, the horizontal frequency and the pixel clock frequency with the possible frequency combinations and outputs the corresponding predetermined resolution as the correct resolution for the video image 12 . The image playback device 50 further contains an adjusting device 74 for adjusting the size of the video image 12 displayed on the screen 68 on the basis of the resolution specified by the control circuit 70 .

The first frequency counter circuit 72 serves to count the number of the pixel clock signals 60 during a predetermined counting period so as to determine the frequency of the pixel clock signals 60 . As can be seen from FIG. 5, it contains a pulse generator 82 for generating periodic pulse signals for marking the predetermined counting period, a counter 86 for counting the number of pixel clock signals 60 within the relevant counting period and providing a corresponding counting value, as well as a buffer 88 for temporary storage of the count value from counter 86 . The periodic pulse signals are used as a load signal for the buffer 88 . When the load signal is received, the buffer 88 loads the count value from the counter 86 . The count in buffer 80 is provided to control circuit 70 to identify the associated resolution. The first frequency counter circuit 72 further includes a delay 94 for delaying the load signal by a predetermined period of time to generate an erase signal. When this clear signal is received, its current count is cleared in counter 86 and a new count of pixel clock signals 60 is initiated. Since the delete signal is generated by delaying the load signal, it is ensured that the count value is deleted after the load.

Fig. 6 shows the resolution table 80 of Fig. 4. As mentioned, the resolution table 80 contains the possible combinations of the frequencies of the vertical synchronization signals 56 , the horizontal synchronization signals 58 and the pixel clock signals 60 and the predetermined resolution for each of these combinations. Since the horizontal synchronization signals 58 are used to control the frequency at which the scan lines 14 of each video image 12 follow one another and the pixel clock signals 60 to control the frequency at which the pixels 60 follow each other within each scan line 14 , the horizontal synchronization signals 58 and the pixel clock signals 60 serve to identify different horizontal resolutions. For example, if the desired resolution is 640 × 400 and the frequency of the vertical synchronization signal 56 is 85 Hz, the frequency of the horizontal synchronization signal 58 is 37.9 kHz and that of the pixel clock signal 60 is 31.5 MHz. If the desired resolution is 720 × 400 and the frequency of the vertical synchronization signals 56 is again 85 Hz, the frequency of the horizontal synchronization signals 58 is likewise 37.9 kHz, but that of the pixel clock signals 60 is approximately 35.5 MHz (compared to 31.5 MHz with the resolution 640 × 400). In this way, the resolutions 640 × 400 and 720 × 400 can be clearly distinguished from one another and the video images 12 can be displayed correctly on the screen 68 .

Let us now consider FIG. 7. FIG. Is a flowchart of the video image signal processing method 100 according to the invention, which is used in the image display device 50 for processing the video signals 52 arriving there. The method 100 has the following steps:

Step 102 : Create the resolution table 80 , which contains all possible combinations of the frequencies of the vertical synchronization signals 56 , the horizontal synchronization signals 58 and the pixel clock signals 60 and a predetermined resolution for each of these combinations.

Step 104 : receiving the video image signals 52 from the video image signal source 40 .

Step 106 : determining the pixel clock frequency from the pixel clock signals 60 , a vertical frequency from the vertical synchronization signals 56 and a horizontal frequency from the horizontal synchronization signals 58 .

Step 108 : Determine a predetermined resolution of the video image 12 from the vertical frequency, the horizontal frequency and the pixel clock frequency by comparing the vertical frequency, the horizontal frequency and the pixel clock frequency with the values specified in the resolution table 80 and outputting the corresponding predetermined resolution as the correct resolution of the Video image 12 .

Step 110 : adjusting the size of the video image 12 reproduced in the image display device 50 on the basis of the determined resolution.

Compared to the prior art, the resolution in the image display device 50 according to the invention is determined not only on the basis of the vertical and horizontal synchronization signals, but also on the basis of the pixel clock signal. In this way, the required resolutions can be correctly determined and a shaky or disproportionate video image can be avoided.

Claims (11)

1. A method for processing video image signals ( 52 ) from a video signal source ( 40 ) in an image display device ( 50 ), which serves to convert the video image signals ( 52 ) into a plurality of video images ( 12 ), each of which a plurality of scan lines, each having a plurality of pixels, wherein the video image signals ( 52 ) a plurality of video signals ( 54 ), a plurality of vertical synchronization signals ( 56 ) for controlling the frequency of the picture change, a plurality of horizontal synchronization signals ( 58 ) for controlling the line change frequency within one contains each video image ( 12 ) and a plurality of pixel clock signals ( 60 ) for controlling the pixel change frequency within each scan line and a vertical frequency of the vertical synchronization signals ( 56 ) and a horizontal frequency of the horizontal synchronization signals ( 58 ) are determined, characterized by the following further Process steps:

• - Determining a pixel clock frequency from the pixel clock signals ( 60 ) and
• - Determining a specific resolution of the video images ( 12 ) from the vertical frequency, the horizontal frequency and the pixel clock frequency.

2. The method according to claim 1, characterized in that the resolution is determined by the following steps:

• - Creating a resolution table ( 80 ) containing all possible combinations of the frequencies of the vertical synchronization signals ( 56 ), the horizontal syn chronization signals ( 58 ) and the pixel clock signals ( 60 ) and a predetermined resolution corresponding to each of these combinations, and
• - Comparing the vertical frequency, the horizontal frequency and the pixel clock frequency with the values specified in the resolution table ( 80 ) and extracting the corresponding predetermined resolution as the desirable resolution of the video images ( 12 ).

3. The method according to claim 1 or 2, characterized in that the pixel clock frequency is determined by counting the number of pixel clock signals ( 60 ) within a predetermined period. 4. An image display device ( 50 ) for displaying video images ( 12 ) on the basis of video image signals ( 52 ) obtained from a video image signal source ( 40 ), wherein each video image ( 12 ) has a plurality of scan lines, each scan line has a plurality of pixels and the video image signals ( 52 ) have a plurality Video signals ( 54 ), a plurality of vertical synchronization signals ( 56 ) for controlling the frame rate, a plurality of horizontal synchronization signals ( 58 ) for controlling the line frequency and a plurality of pixel clock signals ( 60 ) for controlling the pixel frequency within each scan line and contains the image playback device ( 50 )

• a screen ( 68 ) for displaying the video images ( 12 ),
• - One of the vertical synchronization signals ( 56 ) and horizontal synchronization signals ( 58 ) receiving frequency counting circuit ( 76 ) for determining a vertical frequency of the vertical synchronization signals ( 56 ) and a horizontal frequency of the horizontal synchronization signals ( 58 ) and
• - A control circuit ( 70 ) receiving the video image signals ( 52 ) for outputting a predetermined resolution to the screen ( 68 )

characterized in that the image display device ( 50 ) further comprises a further frequency counter circuit ( 72 ) receiving the pixel clock signals ( 60 ) for determining a pixel clock frequency from the pixel clock signals ( 60 ) and the control circuit ( 70 ) has the relevant resolution of the video image ( 12 ) determined from the vertical frequency, the horizontal frequency and the pixel clock frequency. 5. An image display device ( 50 ) according to claim 4, characterized in that the first frequency counter circuit ( 72 ) has a pulse generator ( 82 ) for generating periodic pulse signals for marking a predetermined counting period, and a counter ( 86 ) for counting the number of pixel clock signals ( 60 ) within the predetermined count period determined by the pulse generator ( 82 ) and for generating a count value. 6. image display device ( 50 ) according to claim 5, characterized in that the first frequency counter circuit ( 72 ) further contains a buffer ( 88 ) for temporarily storing the count value from the counter ( 86 ) and the periodic pulse signals each a load signal and a Contain erase signal, the buffer ( 88 ) loads the count value from the counter ( 86 ) when the load signal is received and resets the counter ( 86 ) when the erase signal is received and initiates a new count of the number of pixel clock signals ( 60 ). 7. An image display device ( 50 ) according to claim 6, characterized in that the first frequency counting circuit ( 72 ) further comprises a delay device ( 94 ) for delaying the load signals by a predetermined period for the generation of the delete signals. 8. image display device ( 50 ) according to any one of the preceding claims, characterized in that the control circuit ( 70 ) has a resolution table ( 80 ), all possible combinations of the frequencies of the vertical syn chronization signals ( 56 ), the horizontal Synchroni sationssignale ( 58 ) and containing the pixel clock signals ( 60 ) and a predetermined resolution for each of these combinations and comparing the vertical frequency, the horizontal frequency and the pixel clock frequency with the values in the resolution table ( 80 ) and the corresponding predetermined resolution as the correct resolution of the video image ( 12 ) issues. 9. Image display device ( 50 ) according to one of the preceding claims, characterized in that it further comprises an adjusting device ( 74 ) for adjusting the size of the video images ( 12 ) reproduced on the screen ( 68 ) on the basis of the determined by the control circuit ( 70 ) has output resolution. 10. Image display device ( 50 ) according to one of claims 4 to 9, characterized in that the screen ( 68 ) is an LCD screen. 11. An image display device ( 50 ) according to one of claims 4 to 9, characterized in that the screen ( 68 ) is a digital cathode ray tube monitor.