KR20030067363A - Image Decoder of Image Processor System - Google Patents

Abstract

PURPOSE: A video decoder of a video processing system is provided to stably extract effective video data even for external input synchronous signals in various forms. CONSTITUTION: A video decoder of a video processing system includes a horizontal synchronous signal processor(10), a vertical synchronous signal processor(20), and an effective data extractor(30). The horizontal synchronous signal processor receives an external horizontal synchronous signal, and bypasses the external horizontal synchronous signal or re-generate a horizontal synchronous signal having a reference point fixed to a position having a predetermined distance from an effective data region according as a reference point of the received horizontal synchronous signal is identical to a synchronous generation reference point of the video processing system or not. The vertical synchronous signal processor receives a vertical synchronous signal and outputs the signal, or generates a vertical synchronous signal having a reference point fixed to a position having a predetermined distance from the effective data region using the horizontal synchronous signal generated by the horizontal synchronous signal processor. The effective data extractor receives video information according to the horizontal and vertical synchronous signals to extract effective data.

Description

Image Decoder of Image Processor System

The present invention relates to the field of receiving, processing, and storing an image input from an external device in an image processing system or related IC, and more particularly, to a method for extracting external input image data of an image processing system and a synchronization signal generating device therefor. will be.

In order to extract only necessary image data from an externally input image signal, a synchronization signal as a reference in an image processing system is required.

However, some manufacturers may not receive and process the output of some products because the reference point of the synchronization signal provided by the image processing system is not constant.

However, if the system is designed for all cases, the cost of the effect increases and the structure becomes inefficient.

Therefore, the consistency of the reference signal is required for the efficiency of the system.

1 illustrates the structure of a general digital imaging system.

As shown in FIG. 1, the digital imaging system has a form in which only valid image data (effective area) is extracted from data input from the outside, stored in a memory, or processed and output.

In order to extract valid image data, accurate position and size information of the valid image data is input by the user to the digital imaging system.

Of course, when the user directly inputs the position and size information of the valid image data, it is generally applicable only when the analog image is digitized.

However, even in the case of digital standard images, only some of the valid image data may need to be extracted according to the detailed functions of the system, so the position and size information of the input data is essential.

Therefore, in a video receiving system that receives and processes an external video signal (input data), it is necessary to extract the desired video data by inputting, converting, and reproducing the video data according to a synchronization signal as a reference.

FIG. 2A illustrates input vertical synchronization and input horizontal synchronization of a general interlaced type.

2B illustrates the relationship between the input vertical sync and the input horizontal sync and the effective data area.

2A and 2B illustrate a general configuration of a video signal obtained by separating a sync signal and a video signal from a composite video signal.

The separated video signal can be largely classified into a horizontal sync signal, a vertical sync signal, and video data.

In the interlaced scanning method as shown in FIG. 2A, the horizontal synchronizing signal and the vertical synchronizing signal have a predetermined correlation with each other according to the scanning method. In the interlaced scanning method, it is understood that the relationship between the horizontal and vertical synchronizing signals is different for each field. Can be.

In other words, the interlaced scan method is divided into a top field and a bottom field, and since the NTSC method has 525 scan lines per field, 262.5 scan lines are allocated to the top field and the bottom field, respectively. The position of the horizontal sync at the boundary varies.

As shown in FIG. 2B, a meaningful effective data area of the image data exists after a certain line of the vertical sync signal as shown in the upper part of FIG. 2B and after a certain clock in the horizontal sync signal as shown in the lower part of FIG. 2B. Able to know.

3A shows in detail the relationship between the input horizontal synchronization signal and the area of valid data.

3B shows the positions of the general PAL type input vertical synchronization signal and the effective data area.

That is, FIGS. 3A and 3B illustrate a method of indicating accurate position information of valid data in a signal as shown in FIG. 2B.

First, a specific reference point is required to input accurate location information.

For example, as shown in FIG. 3A, the positional information of the valid data area is input depending on how many clocks are at the falling point of the horizontal synchronization signal or at which clocks the rising point is located at the rising point. .

Also, as in the case of the vertical synchronization signal, as shown in FIG. 3B, the number of lines corresponds to the number of lines based on the falling timing of the input vertical synchronization or the number of lines based on the rising timing of the vertical synchronization. The location information of the valid data area is input in the same manner.

However, in the process of separating the sync signal and the video data from the composite video signal such as NTSC / PAL, due to the influence of the PLL and the manufacturer's hardware structural difference, the fine signal fluctuation or distortion of the sync signal occurs, so that the position of the effective data is sometimes line-by-field or field. There is a case where an error of the inputted location information occurs due to the difference.

For example, when the positional information is fixed in a situation where the horizontal synchronizing signal is minutely changed, the value of the valid data is changed in a horizontal unit so that the output image is jittered from side to side.

Referring to FIG. 3A, when the rising time is shaken while the position information is input based on the rising time of the horizontal synchronization signal, the distance to the valid data is changed in units of lines, and thus the starting position of each line is changed.

In addition, referring to FIG. 3B, even in the case of the vertical synchronization signal, when the starting point of one line is regarded as the polling time or the rising time of the vertical synchronization signal, the distance to the valid data is 6 lines in the first field based on the rising time. In the first field you can see that it is 7 lines.

In this case, the vertical inversion on the screen occurs because the fields are inverted and input.

Accordingly, an object of the present invention is to stably extract valid image data with respect to various types of external input synchronization signals.

1 is a structural diagram of a general digital imaging system.

Fig. 2A is a schematic diagram of input vertical synchronization and input horizontal synchronization of a general interlaced type.

Fig. 2B is a schematic diagram showing the relationship between input vertical sync and input horizontal sync and an effective data area.

Fig. 3A is a schematic diagram showing the relationship between the input horizontal synchronization signal and the area of valid data.

Fig. 3B is a schematic diagram showing a relationship between an input vertical synchronization signal of a general PAL type and an effective data area.

4 is a block diagram of an image decoder of an image processing system according to the present invention;

5A and 5B are diagrams illustrating a horizontal synchronization and vertical synchronization processing operation using the horizontal synchronization signal processing unit and the vertical synchronization signal processing unit of the image decoder shown in FIG.

* Explanation of symbols for main parts of the drawings

10: horizontal synchronization signal processing unit

20: vertical synchronization signal processing unit

30: valid data extraction unit

A feature of the image decoder of the image processing system according to the present invention for achieving the above object is to input an external horizontal sync signal, and according to whether the reference point of the input horizontal sync signal and the sync generation reference point of the image processing system are the same. A horizontal synchronizing signal processing unit for bypassing and outputting the horizontal synchronizing signal or regenerating and outputting a horizontal synchronizing signal having a reference point fixed to the effective data area and a predetermined width position; A vertical sync having an input vertical sync signal and outputting it as a vertical sync signal as it is, or having a reference point fixed to a valid data area and a predetermined width position based on a width determined using a horizontal sync signal generated by the horizontal sync signal processor. A vertical sync signal processor for generating and outputting a signal; And a valid data extractor configured to receive image information and extract valid data according to the horizontal and vertical sync signals output from the horizontal and vertical sync signal processors.

When the reference point of the external horizontal synchronization signal is the same as the synchronization generation reference point of the image processing system, the horizontal synchronization signal processor bypasses and outputs the external horizontal synchronization signal, and the reference point of the external horizontal synchronization signal is the image processing system. If it is not the same as the synchronization generation reference point, the width information is input to generate a horizontal synchronization signal having a valid data point and a reference point fixed at a predetermined width position.

The width information has a variable value with respect to the external horizontal synchronization signal, but keeps the fixed reference point the same.

The vertical synchronizing signal processing unit varies the predetermined width for each field with respect to the input vertical synchronizing signal.

The vertical synchronizing signal processing unit inputs an input vertical synchronizing signal and uses the horizontal synchronizing signal generated by the horizontal synchronizing signal processing unit according to whether the reference point of the input vertical synchronizing signal is equal to the synchronization generating reference point of the image processing system. The sync signal is bypassed and output, or a horizontal sync signal having a reference point fixed to the effective data area and a predetermined width position is regenerated and output.

The operation according to the features of the present invention as described above is divided into a reference point (falling or rising) of the input synchronization signal, by using the internal re-create the synchronization signal according to the reference point or by using the input signal as it is various types of external input synchronization signal It is possible to stably extract valid image data.

In this case, the synchronization generation reference point of the image processing system is designed to be fixed as one, and the synchronization is reproduced or used as it is according to the internally fixed synchronization generation reference point during external horizontal and vertical synchronization input processing.

When the synchronization signal is regenerated, its width can be changed. In the case of horizontal synchronization, the width is regenerated based on the predetermined width regardless of the format of the input image. In the case of the vertical synchronization, the width is generated based on the predetermined width. In order to prepare for this, a certain line can be changed per field.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

A preferred embodiment of an apparatus for generating a synchronization signal of an image decoder of an image processing system according to the present invention will be described below with reference to the accompanying drawings.

4 is a block diagram of an image decoder of an image processing system according to the present invention.

As shown in FIG. 4, the horizontal synchronization signal processing unit 10 inputs an input horizontal synchronization signal, and generates the input horizontal synchronization signal according to whether the reference point of the input horizontal synchronization signal is identical to the synchronization generation reference point of the image processing system. Bypass outputs, or regenerates and outputs a horizontal synchronizing signal having a reference point fixed to the effective data area and a fixed width position.

When the reference point of the input horizontal sync signal is the same as the sync generation reference point of the image processing system, the horizontal sync signal processing unit 10 bypasses the input horizontal sync signal and outputs the reference point of the input horizontal sync signal. If it is not the same as the synchronization generation reference point of the image processing system, width information is input and a horizontal synchronization signal having a valid data area and a reference point fixed to a predetermined width position is generated and output.

When the reference point of the horizontal synchronization signal is not the same as the reference point for generating the synchronization of the image processing system, the horizontal synchronization signal processing unit 10 has a variable value and the width information of the horizontal synchronization signal is fixed. It remains the same so that the reference point of the regenerated horizontal sync signal is always coincident.

The vertical synchronizing signal processor 20 generates a vertical synchronizing signal using the generated horizontal synchronizing signal.

The vertical synchronizing signal processing unit 20 sets a new width based on a predetermined width by using the generated horizontal synchronizing signal regardless of whether the reference point of the input vertical synchronizing signal is a polling time or a rising time. Output a vertical sync signal with a reference point fixed to.

When an arbitrary waveform is input to the image processing system, the vertical synchronizing signal processor 20 generates a vertical synchronizing signal by varying the predetermined width for each field with respect to the arbitrary waveform.

Alternatively, the vertical synchronizing signal processing unit 20 receives an input vertical synchronizing signal and uses the horizontal synchronizing signal generated by the horizontal synchronizing signal processing unit 10 to determine the reference point of the input vertical synchronizing signal and the synchronization generating reference point of the image processing system. The input vertical sync signal is bypassed and output according to the same condition, or the horizontal sync signal having a reference point fixed to a valid data area and a predetermined width position is regenerated and output.

In this case, when the reference point of the input vertical synchronization signal is the same as the synchronization generation reference point of the image processing system, the vertical synchronization signal processing unit 20 bypasses the input vertical synchronization signal and outputs the reference point of the input vertical synchronization signal. If it is not the same as the synchronization generation reference point of the image processing system, width information is input, and a vertical synchronization signal having a valid data area and a reference point fixed to a predetermined width position is generated and output.

The valid data extracting unit 30 receives image information (effective data size and position) according to the horizontal and vertical synchronizing signals output from the horizontal and vertical synchronizing signal processing units 10 and 20 to extract valid data.

With the above configuration, the composite video decoder of the image processing system inputs the sync signal and the video signal separately from the complex video signal, and inputs the horizontal and vertical components of the separated sync signal, that is, the input horizontal and vertical sync signals. Generate a horizontal and vertical synchronization signal having a fixed reference point at a fixed position from the effective data region.

The reference point of the image processing system is designed in a fixed situation, and the synchronization signal is internally used or regenerated as described above when the external synchronization input signal is processed.

Of course, the synchronization generation reference point of such an image processing system is slightly different for each manufacturer or product, but in most cases, it is based on the polling time of the external input sync signal, and some of it is based on the rising time.

Considering both of these cases, designing a system can be both inefficient and prone to problems.

Therefore, images of two reference points are internally used as one reference point.

5A and 5B illustrate horizontal and vertical synchronization processing operations using the horizontal synchronization signal processing unit 10 and the vertical synchronization signal processing unit 20 of the image decoder shown in FIG.

Since the horizontal and vertical sync signals decoded by the complex video decoder of the image processing system are fixed to one of the polling or rising time points, two cases may be considered depending on the synchronization reproduction reference point (polling time or rising time point) of the image processing system. have.

First, when the polling time of the input sync signal is stable, and second, when the rising time of the input sync signal is stable, the horizontal and vertical sync signal processing units 10 and 20 are the sync reproduction reference points of the image processing system. The synchronization signal information (reference point mode, width information) is received from the outside depending on whether the stabilization time (reference point) of the input synchronization signal is the same.

Among the input synchronization signal information, the reference point mode includes an input synchronization bypass mode and a synchronization signal regeneration mode. The input synchronization bypass mode operates when the synchronization reproduction reference point of the image processing system is the same as the stable time point of the input synchronization signal. The synchronous signal regeneration mode operates when the synchronous reproducing reference point of the image processing system is not the same as the stable point of time of the input synchronous signal.

It is assumed that the synchronous reproduction reference point of the image processing system is designed based on the rising time.

That is, it is assumed that the valid data extractor 30 of FIG. 4 is designed based on the rising time of the synchronization signal for all the synchronization signals.

At this time, when the input horizontal synchronizing signal is a signal having a polling time as a stable point (reference point), the horizontal synchronizing signal processing unit 10 operates in the synchronizing signal regeneration mode under the control of the CPU, regardless of the format of the input video signal. As shown in (2), the reference point C is fixed by the width information A input at the time of polling the input horizontal synchronization signal, and the width information is adjusted to fix the reference point C for various input horizontal image signals. , Always provides horizontal positional information B of constant valid data.

That is, the width information A may have a variable value, and may have horizontal position information B having a predetermined width for each synchronization signal up to the effective data area.

Therefore, when the position of the valid data is specified based on the reference point C of the newly generated sync signal, the valid data extracting unit 30 may obtain stable data in any case.

Similarly, it is assumed that the valid data extractor 30 of FIG. 4 is designed based on the rising time of the synchronization signal for all the synchronization signals.

At this time, when the input horizontal synchronizing signal is a signal having a rising time as a stable point (reference point), the horizontal synchronizing signal processing unit 10 operates in the input synchronizing bypass mode under the control of the CPU, and the input horizontal synchronizing signal is operated as shown in (3) of FIG. The synchronization signal is bypassed as it is, and the valid data extraction section 30 is provided with horizontal positional information D of valid data.

As mentioned in the above configuration, in the case of generating the vertical synchronizing signal, a method of setting and generating a new width regardless of whether the reference point of the input vertical synchronizing signal is a polling time or a rising time (a method of updating position information for each field). This is effective.

The reason is that in the vertical synchronizing signal, the waveform of the vertical synchronizing signal itself varies with the type of the image signal together with the stable reference point.

For example, even if the valid data extractor 30 is designed with respect to the rising time and the reference vertical synchronization input point is the rising time, as shown in FIG. 5B, the number of lines from the reference vertical input point to the valid data is 1 per field. Trouble may occur.

Therefore, if the synchronization generation reference point of the image processing system is the rising point, and the reference point of the input vertical synchronization is the polling point, the new width may be set in accordance with the rising point or the new width may be set in accordance with the polling point.

In this case, although there may be a method of updating the position information for each field, the method of updating the position information for each field and the method of selecting the reference point for the uniformity of the system (the same as the reference point of the synchronization generation reference point of the image processing system and the input vertical synchronization). It is very advantageous to be able to use a method of generating a vertical synchronizing signal at the same time, and to compensate for a delay phenomenon of a vertical synchronizing signal which is often generated when separating a synchronizing signal from a composite video signal.

That is, in the vertical synchronizing signal processing unit 20, the method of regenerating the vertical synchronizing signal is polling when the synchronizing generation reference point of the image processing system is the rising point and the reference point of the input vertical synchronizing signal is the polling point as shown in (2) of FIG. 5B. The vertical synchronization signal may be generated to be a rising point F after a predetermined line at the point E.

Similarly, when the synchronization processing reference point is at the rising point and the reference point of the input vertical synchronization signal is at the rising point, the image processing system basically fits the input rising point, but the width thereof can be expanded by a predetermined line compared to the rising point.

As a result, since the image decoder is fixed in the system, the horizontal synchronization signal is generated by selecting the case (2) or (3) of FIG. 5A in the case of horizontal synchronization according to the synchronization generation reference point of the image decoder adopted in the system development stage.

In the case of the vertical synchronization, the synchronization is internally reproduced, but the width thereof can be changed for each field so that it can be applied to an image of any format.

As described above, the image decoder of the image processing system according to the present invention has the following effects.

In an image processing system that receives and processes an external video signal, the input signal is used as it is or internally fixed to a reference point to output a synchronization signal generated by the reference point, thereby stably valid for various types of external input synchronization signals. You can extract data.

This can be applied to any device that inputs, converts, and plays back image data, and can be effectively applied to devices that provide various input modes such as digital TV.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (6)

An external horizontal synchronization signal is input, and the external horizontal synchronization signal is output by bypassing the external horizontal synchronization signal according to whether the reference point of the input horizontal synchronization signal is identical to the synchronization generation reference point of the image processing system, or is fixed to a valid data area and a fixed width position. A horizontal synchronizing signal processing unit for regenerating and outputting a horizontal synchronizing signal having a? A vertical sync having an input vertical sync signal and outputting it as a vertical sync signal as it is, or having a reference point fixed to a valid data area and a predetermined width position based on a width determined using a horizontal sync signal generated by the horizontal sync signal processor. A vertical sync signal processor for generating and outputting a signal; And a valid data extractor configured to receive image information and extract valid data according to horizontal and vertical sync signals output from the horizontal and vertical sync signal processors. The method of claim 1, wherein the horizontal synchronization signal processing unit If the reference point of the external horizontal synchronization signal is the same as the synchronization generation reference point of the image processing system, bypassing and outputting the external horizontal synchronization signal, When the reference point of the external horizontal synchronization signal is not the same as the synchronization generation reference point of the image processing system, width information is input and generates and outputs a horizontal synchronization signal having a valid data area and a reference point fixed at a predetermined width position. An image decoder of an image processing system. The image decoder of claim 2, wherein the width information has a variable value with respect to the external horizontal synchronization signal and maintains the fixed reference point. The image decoder of claim 1, wherein the vertical synchronization signal processor is configured to vary the predetermined width for each field with respect to the input vertical synchronization signal. The method of claim 1, wherein the vertical synchronization signal processing unit Input an input vertical sync signal, and bypass the input vertical sync signal according to whether the reference point of the input vertical sync signal and the sync generation reference point of the image processing system are the same by using the horizontal sync signal generated by the horizontal sync signal processor. Or regenerates and outputs a vertical synchronizing signal having a reference point fixed to a valid data area and a predetermined width position. The method of claim 5, wherein the vertical synchronization signal processing unit When the reference point of the input vertical synchronization signal is the same as the synchronization generation reference point of the image processing system, bypassing and outputting the input vertical synchronization signal, When the reference point of the input vertical synchronization signal is not the same as the synchronization generation reference point of the image processing system, width information is input and a vertical synchronization signal having a reference point fixed to a valid data area and a predetermined width position is generated and outputted. An image decoder of an image processing system.