KR20010103339A - Apparatus for converting format - Google Patents

Abstract

A format conversion apparatus in a vertical direction, in particular, by sharing a part of a line memory to store a luminance signal or a color signal, and storing a luminance signal or a color signal in the common line memory according to a format conversion mode, It is possible to efficiently perform vertical format conversion using a minimum line memory. Also, by changing the structure of the line memory according to the size of the input / output image, the format conversion in the vertical direction can be performed more effectively.

Description

Apparatus for converting format

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to digital TVs, and more particularly, to an image format conversion apparatus for converting and outputting an input image into another form.

With the introduction of digital TVs and the development of various display devices, more various types of images can be input and output than conventional analog TVs.

For example, in the case of a digital TV, an image having various sizes such as a high definition (HD) level image, a standard definition (SD) level image, a computer video signal, and an analog TV signal may be input. In addition, in the case of digital TV, various types of displays such as LCD (Liquid Crystal Display), PDP (Plasma Display Panel), and computer, which use sequential scanning, as well as conventional CRT or Projection TV using interlaced scanning The device will be used and requires various output formats accordingly.

Therefore, in order to convert input images of various formats into output images of other formats, a format conversion apparatus is essentially used.

In this case, only the pixel delay function is required for format conversion in the horizontal direction, but an expensive line memory is required for format conversion in the vertical direction. In addition, the horizontal format conversion has a simple function, while the vertical format conversion requires a variety of image processing. For example, in order to convert an existing interlaced image into a high quality image, a sequential scanning method must be applied, and a high quality image can be processed simultaneously with the existing standard image quality image. This requires a large amount of line memory, which requires effective use of line memory.

FIG. 1 is a block diagram illustrating a general vertical format converting apparatus. The luminance signal line memory unit 11 including a plurality of line memories stores an input luminance signal (Yin) in units of lines and then converts the luminance signal vertical format converter ( 12) The luminance signal vertical format converter 12 performs a format conversion on the luminance signal output from the luminance signal line memory unit 11 in a vertical direction according to an output size.

In addition, the color signal line memory unit 13 including a plurality of line memories stores the input color signal Cin in units of lines, and the color signal vertical format converter 14 is the color signal line memory unit 13. Converts the color signal output from the vertical direction to the output size.

However, the vertical format conversion apparatus as shown in FIG. 1 has a disadvantage in that the line memory for the luminance signal and the line signal for the color signal are separately used so that the line memory cannot be effectively used.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to use a line memory by sharing a line signal for a luminance signal and a line memory for a color signal with each other and changing the structure of the line memory according to the type of an input image. It is to provide a format conversion apparatus for optimizing the.

1 is a block diagram of a general format conversion apparatus

2 is a block diagram of a format conversion apparatus according to the present invention;

3 is a detailed block diagram of a vertical filter and a sequential scanning unit of FIG. 2.

4 is a block diagram showing the structure of the format conversion apparatus of FIG. 2 in the progressive scan conversion mode;

FIG. 5 is a block diagram illustrating a structure of the format conversion apparatus of FIG. 2 in an image reduction conversion mode. FIG.

6 is a block diagram showing the structure of the format conversion apparatus of FIG. 2 in the large screen conversion mode;

7A and 7B are block diagrams showing the detailed structure of the line memory of FIG. 2 in the large screen conversion mode, the progressive scan conversion mode, and the image reduction mode.

Explanation of symbols for main parts of the drawings

20: line memory section 21: line memory section for luminance signal

22: common line memory section 23: color signal line memory section

24: mux 30: data classification

40 vertical filter and sequential scanning unit

50: luminance signal vertical format converter

60: color signal vertical format converter 70: data controller

A format conversion apparatus according to the present invention for achieving the above object, share a portion of the line memory to store the luminance signal or color signal in the common line memory according to the format conversion mode, and also the size of the input image By changing the structure of the line memory according to the format conversion, it is characterized in that the limited line memory is effectively used.

Hardware for implementing this is a data control unit for generating a control signal to determine a format conversion mode from the format information of the input image and the output image and to perform a vertical format conversion in the determined mode, and is input by the control signal of the data control unit A luminance signal line memory unit for storing only luminance signals among image signals, a color memory line memory unit for storing only color signals among image signals input by a control signal of the data controller, and a control signal of the data controller A luminance signal processing for performing vertical format conversion by receiving a luminance signal output from the common line memory unit for storing a luminance signal or a color signal among the image signals, and the luminance signal line memory unit and the shared line memory unit. Vertical format conversion unit and the color signal line The input and output data paths are controlled by a color signal processing vertical format converter for receiving a color signal output from a memory unit and a shared line memory unit and performing vertical format conversion, and a control signal of the data controller. And a data classifying unit for selectively outputting the output of the line memory unit to the vertical format converting unit for luminance signal processing or the vertical format converting unit for color signal processing.

The data controller generates a control signal such that the luminance signal is stored after being output to the common line memory unit when sequential scanning of the input image is required.

When the vertical filtering of the input image is required, the data controller generates a control signal such that the luminance signal is stored after being output to the common line memory unit.

When the size of the high-quality input image is enlarged, the data controller configures a plurality of line memories of the line signal unit for the luminance signal as one line memory to store the luminance signals, and stores the plurality of color signal line memory units and the common line memory unit. It is characterized in that the control signal is generated so that the color signals are stored by configuring one line memory as one line memory.

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.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating a format conversion apparatus according to the present invention, and shows only a part related to the format conversion in the vertical direction.

2, the line memory unit 20, the data classifying unit 30, the vertical filter & de-interlacer 40, the luminance signal vertical format converter 50, and the color signal vertical It consists of a format conversion part 60 and the data control part 70.

In this case, the line memory unit 20 is composed of a plurality of line memories, and stores the input image data in units of lines. The line memory unit 20 is composed of at least one or more line memories 21-1 to 21-4. A luminance signal line memory section 21 for storing only an image of a color signal, at least one line memory 23-1, 23-2, and a color signal line memory section 23 for storing only an image of a color component, and at least It consists of one or more line memories 22-1, 22-2, and a common line memory section 22 for selectively storing luminance and color components.

The vertical filter and the sequential scanning unit 40 convert a luminance signal of the interlaced scanning method into a luminance signal of the sequential scanning method, as shown in FIG. 3. A sequential scanning section 42 and a mux 43 that selects the output of the vertical filter 41 or the output of the sequential scanning section 42 and outputs them to the luminance signal vertical format converter 50.

That is, the vertical filter 41 and the sequential scanning unit 42 are configured in parallel as shown in FIG. 3, and only one block operates according to the control signal of the data controller 70. For example, when converting an interlaced scan image into a sequential scan image, the input image is input to the sequential scanning unit 42 and sequentially scanned, and then to the luminance signal vertical format converter 50 through the MUX 43. When the high-quality image is converted into a standard-definition image, the input image is input to the vertical filter 41, filtered, and then output to the luminance signal vertical format converter 50 through the mux 43.

Here, when vertical filtering or sequential scanning is required during format conversion, the luminance signal is stored in the shared line memory unit 22. Then, in the case of Fig. 2, the number of line memories used for storing the luminance signal is six. This is an example when the number of taps of the vertical filter 41 is five, and the number of line memories varies depending on the number of taps of the vertical filter 41.

In addition, the front end of the shared line memory unit 22 is provided with a mux 24 for selecting any one of the input luminance signal and the color signal to store in the shared line memory unit 22. That is, the MUX 24 selects a luminance signal from among image signals inputted according to the format conversion mode provided by the data controller 70 or selects a color signal and outputs the color signal to the shared line memory unit 22.

Accordingly, the luminance signal may be stored in the line memories 22-1 and 22-2 of the common line memory unit 22 according to the current format conversion mode, or the color signal may be stored. For example, an image signal (eg, a luminance signal) to be stored depending on whether the format conversion mode is a mode for performing sequential scanning, a mode for performing vertical filtering to reduce an image, or a mode for performing large screen format conversion. Or a color signal), and an operation mode is determined by the data controller 70 and the data classifier 30.

The data classifying unit 30 is a vertical filter and a sequential scanning unit, which are format conversion units for processing luminance signals, by the control of the data control unit 70, that is, the signals stored in the common line memory unit 22 according to a format conversion mode. And output to the color signal vertical format converter 60, which is the vertical filter 41, the sequential scanning section 42, or the format converter for color signal processing. In addition, the data classifying unit 30 may convert the luminance signal stored in the luminance signal line memory 21 according to a format conversion mode into a vertical filter 41 or a sequential scanning unit 42 of the sequential scanning unit 40. Alternatively, the luminance signal is directly output to the luminance signal vertical format converter 50, and the color signal stored in the color signal line memory 23 is output to the color signal vertical format converter 60. In this case, the control of the complex classification task of the data classification unit 30 is performed by the data control unit 70.

That is, the data control unit 70 stores the input selection of the muxes 24 and 43, the data storage of the line signals 21, 22 and 23 for the luminance signal, the common and the color signal, and the data classification unit 30 according to the format conversion mode. Control the sorting operation.

Herein, the data controller 70 detects a format of an input video signal from an input video signal or an input video format designated by a user, and detects a format of an output video signal from an output device or an output video format designated by a user to format conversion. Determine the mode. That is, the data controller 70 changes the structure of the line memory of the line memory unit 20 according to the determined format conversion mode, controls the input selection of the muxes 24 and 43, and the data classifier 30. Control the classification of data.

For example, the format conversion mode includes a sequential scan conversion mode for converting an interlaced scanning video signal into a sequential scanning video signal, an image reduction mode for filtering the input video in a vertical direction, and outputting the input image to a large screen. There may be a large screen mode. In addition, there may be a conversion mode for converting a high quality image into a high quality image of a different size, and a conversion mode for converting an image of sequential scanning standard definition to an image of a sequential scanning standard definition of another size.

If the input image is an SD class image of standard quality of interlaced scanning method and the HD image of high quality of output image, sequential scanning is required. In this case, the data control unit 70 controls the structure of the line memory unit 20 and the structure of the format conversion unit for luminance signal processing as shown in FIG. 4. That is, the mux 24 selects the luminance signal and outputs the luminance signal to the shared line memory unit 22 under the control of the data control unit 70. Therefore, the luminance signal is stored in the shared line memory unit 22. The luminance signals stored in the luminance signal line memory unit 21 and the common memory unit 22 are sequentially scanned by the scanning unit 42, and then output to the luminance signal vertical format converter 50. The color signal stored in the color signal line memory section 23 is directly output to the color signal format converter 60. That is, since the color signal is guaranteed enough image quality without performing sequential scanning conversion, the color signal output from the color signal line memory unit 23 is directly output to the color signal vertical format conversion unit 60.

As described above, the sequential scanning unit 42 converts the interlaced scanning image into a sequential scanning image. This is because serious image deterioration may occur when a format conversion of an interlaced scan image into a high quality image is performed immediately. Therefore, in order to obtain normal picture quality, the interlaced scan image is first converted into a sequential scan image by the sequential scanning unit 42 and then the sequential scan image is converted into a high quality image by the luminance signal vertical format converter 50. In this case, in order to obtain a sequential scanning method from an interlaced scanning method, images of several fields are required. If the sequential scanning unit 42 uses six line memories as shown in FIG. 4, in this case, sequential scanning may be performed using one or two line memories in four consecutive field images. Here, the sequential scanning method may vary according to the number of the line memories. The luminance signal vertical format converter 50 performs format conversion in a vertical direction. For example, the luminance signal vertical format converter 50 generates necessary lines by interpolating image information of two lines Yout0 and Yout1 at a predetermined ratio.

For example, if the input image is a 720 (H) * 480 (V) interlaced scan image and the output image is a 1920 (H) * 1080 (V) sequential scan image, the input image is 720 ( H) * 960 (V) is converted into a progressive scan image. The 720 (H) * 960 (V) sequential scanned image is inputted to the luminance signal vertical format converter 50 and converted into a 720 (H) * 1080 (V) sequential scanned image. In this case, when the horizontal format converter is provided in front of the vertical format converter, the luminance signal vertical format converter 50 finally outputs an image of 1920 (H) * 1080 (V) sequential scanning, and the horizontal format converter is If it is provided at the rear end of the vertical format conversion apparatus, 720 (H) * 1020 (V) sequential scanning image is input to the rear horizontal format converting unit and converted into 1920 (H) * 1020 (V) sequential scanning image. In the present invention, the horizontal format converter may be in front of the vertical format converter, or may be in the rear stage.

On the other hand, when the input image is a high-definition image of HD class and the output image is a standard-definition image of SD grade, that is, when converting a high-definition image into a standard definition image, filtering in the vertical direction is necessary. If the filtering in the vertical direction is not performed, aliasing occurs and the high frequency portion of the image is changed to a low frequency component, thereby making the image annoying.

For example, if the format of the input image is 1920 (H) * 1080 (V) and the format of the output image is 720 (H) * 480 (V), the filtering should be performed in the vertical direction. Here, filtering for the horizontal direction is also required, but in the present invention, only the vertical format conversion is described, and thus the description for the horizontal direction is omitted.

Therefore, when the determined format conversion mode is an image reduction mode for reducing from a high definition image to a standard definition image, the data control unit 70 converts the structure of the line memory unit 20 and the format conversion for luminance signal processing so as to have a structure as shown in FIG. 5. Control the structure of the negative.

That is, the mux 24 selects the luminance signal and outputs the luminance signal to the shared line memory unit 22 under the control of the data control unit 70. Therefore, the luminance signal is stored in the shared line memory unit 22. The luminance signals stored in the luminance signal line memory unit 21 and the common memory unit 22 are filtered in the vertical direction through the vertical filter 41 and then output to the luminance signal vertical format converter 50. That is, the vertical filter 41 receives the luminance signals of the lines output from the luminance signal line memory unit 21 and the common memory unit 22 in units of lines and performs vertical filtering. The luminance signal vertical format converter 50 performs format conversion in the vertical direction. For example, the luminance signal vertical format converter 50 performs line reduction by using image information of two lines Yout0 and Yout1.

The color signal stored in the color signal line memory section 23 is directly output to the color signal format converter 60. In this case, since the color signal is guaranteed enough image quality without performing vertical filtering, the color signal output from the color signal line memory unit 23 is directly output to the color signal vertical format converter 60.

On the other hand, when the input is a high-definition image of HD class and the output is a high-definition image of HD class, there are many cases where sequential scanning or vertical filtering is not necessary for proper format conversion. Instead, larger line memory is required compared to standard definition video. In this case, as shown in FIG. 6, two line memories are connected in series to form a line memory that is relatively larger than a standard definition image conversion, and the luminance signal is vertical without going through the vertical filter 41 or the sequential scanning unit 42. The data of the line memory is input to the format converter 50. In this case, since only two line data are required for vertical format conversion, the configuration may be performed as shown in FIG. In this case, the same format conversion may be performed on the luminance component and the color component. That is, the color signal is selected through the mux 24 under the control of the data control unit 70 and stored in the common line memory unit 22. Here, read / write addressing of the luminance signal, common and color signal line memory units 21, 22, and 23 is performed by the data controller 70.

At this time, if the filter coefficient of the vertical filter 41 is properly adjusted, a portion of the input image may be bypassed as it is without vertical filtering and output to the luminance signal vertical format converter 50. This method can be used when converting a high definition image into a high definition image of a different size or when converting a sequential scanning standard definition image into a sequential scanning standard definition image of another size.

That is, the vertical filter 41 may also perform a function of reinforcing high-frequency components when converting a standard definition image into a high definition image, in addition to removing aliasing when converting the standard definition to a high definition image. Therefore, in the case of converting a standard definition image into a standard definition image or converting a high definition image into a high definition image, incorrect filtering may result in worse image quality than in the case where no filtering is performed. In this case, it is possible to prevent the deterioration of image quality by directly adjusting the filter coefficients and outputting specific input image data. That is, in such a case, it is possible to obtain better image quality by performing format conversion immediately without performing filtering.

FIG. 7 illustrates an example of the actual use of the line memory. Mode A of FIG. 7A is an example of the actual configuration of the line memory used when the high-definition image is converted into a high-definition image of a different size. For example, a line memory capable of storing at least 1280 pixels is required to convert an image having a size of 1280 (H) * 720 (V) into an image having a size of 1920 (H) * 1080 (V). In this case, if two lines of memory capable of storing 960 pixels (120 * 64 = 960 * 8 bits = 960 pixels) are configured in series, a line memory capable of storing 1920 pixels can be configured.

In addition, the mode B of FIG. 7B is an actual example of the line memory used when the sequential scanning unit, the vertical filtering, or the like is performed. That is, in case of a standard-quality interlaced scanning image that requires sequential scanning, a line memory within 768 pixels such as 640 * 480, 704 * 480, 720 * 480, 768 * 480 is required. Accordingly, in this case, by assigning six line memories having 960 pixels to luminance components as in mode B and performing only format conversion in the case of color signals, a total of eight line memories can be effectively used.

On the other hand, in general, since human visual characteristics are insensitive to color signals, sequential scanning conversion or filtering is rarely performed on color signals. In this case, color signal processing requires only the minimum line memory required for vertical format conversion, so that an appropriate picture quality can be obtained. That is, as described above, when converting to an image having a similar size, only the luminance of the luminance signal is required for the format conversion. Otherwise, a relatively large amount of the line memory is required compared to the color signal. In this case, as described above, a little more amount of line memory is allocated to the format conversion for luminance signals in accordance with the format conversion mode, and in another mode, the same amount of line memory is sufficiently allocated to the luminance signal and color signal line memory. Format conversion can be performed effectively using the line memory.

In addition, in the present invention, the sequential scanning method, the vertical filtering method, and the vertical format method are various and known techniques may be used as they are.

As described above, according to the format conversion apparatus according to the present invention, a part of the line memory is shared so as to store a luminance signal or a color signal, and the common line memory is appropriately selected according to the size of the input / output image (ie, the format conversion mode). In this way, efficient format conversion can be performed using a minimum of line memory. In addition, by changing the structure of the line memory according to the size of the input / output image (that is, the format conversion mode), format conversion can be performed more effectively. In particular, if the present invention is applied to the format conversion field of digital TV, it is possible to effectively perform the required format conversion while reducing the cost of the system.

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)

A data controller configured to determine a format conversion mode from the format information of the input image and the output image, and generate a control signal to perform vertical format conversion in the determined mode; A luminance signal line memory unit including at least one line memory and storing only luminance signals among image signals input by a control signal of the data controller; A color memory line memory unit configured of at least one or more line memories and storing only color signals among image signals input by a control signal of the data controller; A common line memory unit including at least one line memory and storing a luminance signal or a color signal among image signals input by a control signal of the data controller; A luminance signal processing vertical format converter for receiving a luminance signal output from the luminance signal line memory unit and a common line memory unit and performing vertical format conversion; A vertical format conversion unit for color signal processing which receives color signals output from the color signal line memory unit and the common line memory unit and performs vertical format conversion; And An input / output data path controlled by a control signal of the data control unit, and including a data classification unit for selectively outputting the output of the common line memory unit to a luminance signal processing vertical format conversion unit or a color signal processing vertical format conversion unit. A format conversion device characterized by the above-mentioned. The method of claim 1, wherein the data control unit And a control signal is generated such that a luminance signal is stored in the shared line memory unit and outputted after a sequential scanning of the input image is required. The method of claim 1, wherein the data control unit And when a vertical filtering of the input image is required, generating a control signal such that a luminance signal is stored in the common line memory unit and then output. The method of claim 1, wherein the data control unit When the size of the high-quality input image is enlarged, a plurality of line memories of the luminance signal line memory unit are configured as one line memory to store luminance signals, and the plurality of line memories of the color signal line memory unit and the common line memory unit are stored. And converting the signal into a single line memory to generate a control signal. The method of claim 1, wherein the format conversion unit for the luminance signal processing A vertical filter which receives the luminance signal output through the data classifying unit and performs vertical filtering; A sequential scanning unit which receives the luminance signal output through the data classification unit and sequentially scans the luminance signal; And a luminance signal vertical format converter for enlarging or reducing the luminance signal output through the vertical filter or the sequential scanning unit in a vertical direction. The method of claim 5, wherein the vertical filter And converting only the size of the input image at a similar image quality, without outputting the input image by the control signal of the data control unit.